Throttle device and refrigeration cycle system with same

The invention claimed is: 1. A throttle device comprising: a tube body provided in a duct to supply a refrigerant, and including open end portions located at two ends to communicate with insides of the duct; a valve seat provided in the tube body, and having a valve port; a needle member provided to be capable of coming close to and moving away from the valve port of the valve seat, and having a tapered portion to control an opening area of the valve port; a biasing member provided between the needle member and one of the open end portions of the tube body, and configured to bias the needle member in a direction to come close to the valve port of the valve seat; and braking means that includes a clearance formed adjacent the needle member for inducing a pressure of the refrigerant such that an outer peripheral surface of a body portion of the needle member is pressed against an inner peripheral surface of the tube body in a radial direction from a central axis of the needle member when the refrigerant passes through the valve port, wherein the induced pressure is attributable to the clearance. 2. The throttle device according to claim 1 , further comprising a stopper member provided between the needle member and the other open end portion of the tube body and configured, in a case where a force applied to the needle member by the pressure of the refrigerant does not exceed a biasing force of the biasing member, to be in contact with and support a front end portion of the tapered portion of the needle member biased by the basing member such that a clearance is formed between the tapered portion of the needle member and a periphery of the valve port. 3. The throttle device according to claim 1 , wherein the clearance is formed by a flat surface formed at a position away from the center axis in the body portion of the needle member, and an inner peripheral surface of the tube body opposed to the flat surface. 4. A throttle device comprising: a guide tube provided in a duct to supply a refrigerant, and having open end portions located at two ends to communicate with insides of the duct; a valve seat formed in the guide tube, and having a valve port; at least one communication path formed in a portion of the guide tube adjacent to the valve seat, and configured to establish communication between an inner peripheral part and an outer peripheral part of the guide tube; a needle member provided to be capable of coming close to and moving away from the valve port of the valve seat, and having a tapered portion to control an opening area of the valve port; a biasing member provided between the needle member and one of the open end portions of the guide tube, and configured to bias the needle member in a direction to come close to the valve port of the valve seat; and braking means that includes one of a clearance, a groove, or a slant surface portion formed adjacent the needle member for inducing a pressure of the refrigerant such that an outer peripheral surface of a body portion of the needle member is pressed against an inner peripheral surface of the guide tube in a radial direction from a central axis of the needle member when the refrigerant passes through the valve port, wherein the induced pressure is attributable to one of the clearance, the groove, or the slant surface portion. 5. The throttle device according to claim 4 , further comprising a stopper member provided between the needle member and the other open end portion of the guide tube and configured, in a case where a force applied to the needle member by the pressure of the refrigerant does not exceed a biasing force of the biasing member, to be in contact with and support a front end portion of the tapered portion of the needle member biased by the basing member such that a clearance is formed between the tapered portion of the needle member and a periphery of the valve port. 6. The throttle device according to claim 4 , wherein the clearance is formed by a flat surface formed at a position away from the center axis in the body portion of the needle member, and an inner peripheral surface of the guide tube opposed to the flat surface. 7. The throttle device according to claim 4 , wherein the clearance is formed by the tapered portion of the needle member, and a groove formed in a periphery of the valve port. 8. The throttle device according to claim 4 , wherein the clearance is formed by a flat surface formed at the tapered portion of the needle member, and a periphery of the valve port opposed to the flat surface. 9. The throttle device according to claim 4 , wherein the braking means comprises a groove penetrating the tapered portion of the needle member along a radial direction of the tapered portion. 10. The throttle device according to claim 4 , wherein the slant surface portion is formed at a front end of the needle member. 11. The throttle device according to claim 4 , further comprising a biasing member support portion configured to support the biasing member, wherein when the needle member is moved toward a spring guide portion of the biasing member support portion by a predetermined value or more, a front end of the spring guide portion comes into contact with a front end of the needle member opposed to the front end of the spring guide portion. 12. A refrigeration cycle system comprising: an evaporator; a compressor; and a condenser, wherein the throttle device according to claim 1 is provided in a duct located between an outlet of the condenser and an inlet of the evaporator. 13. A refrigeration cycle system comprising: an evaporator; a compressor; and a condenser, wherein the throttle device according to claim 4 is provided in a duct located between an outlet of the condenser and an inlet of the evaporator.