Scroll compressor

What is claimed is: 1. A scroll compressor, comprising: a casing having a low-pressure portion and a high-pressure portion; an orbiting scroll coupled to a rotary shaft in the low-pressure portion of the casing to perform an orbiting motion; a non-orbiting scroll engaged with the orbiting scroll to form compression chambers and movable relative to the orbiting scroll in an axial direction of the scroll compressor; a back pressure chamber assembly disposed at a rear surface of the non-orbiting scroll to form a back pressure chamber; a first back pressure valve disposed between a first compression chamber of the compression chambers and the back pressure chamber to allow movement of a refrigerant from the first compression chamber to the back pressure chamber while blocking reverse movement of the refrigerant; and a second back pressure valve disposed between the back pressure chamber and a second compression chamber of the compressor chambers and spaced apart from the first back pressure valve, to allow movement of the refrigerant from the back pressure chamber to the second compression chamber while blocking reverse movement of the refrigerant, wherein the first back pressure valve provides communication with the first compression chamber having a relatively lower pressure than a pressure of the second compression chamber, the second back pressure valve providing communication with the second compression chamber, and wherein the second back pressure valve is disposed at a position within a range in which the second compression chamber executes a discharge stroke. 2. The scroll compressor of claim 1 , wherein the first back pressure valve is disposed at a position after the first compression chamber completes a suction stroke. 3. The scroll compressor of claim 1 , wherein the first back pressure valve is disposed in a first back pressure hole that provides communication between the first compression chamber and the back pressure chamber, the first back pressure valve opening and closing the first back pressure hole according to a pressure difference between the first compression chamber and the back pressure chamber, wherein the second back pressure valve is disposed in a second back pressure hole that provides communication between the back pressure chamber and the second compression chamber, the second back pressure valve opening and closing the second back pressure hole according to a pressure difference between the second compression chamber and the back pressure chamber, and wherein the first back pressure hole and the second back pressure hole are spaced apart by a predetermined rotational angle in a direction in which the compression chambers are formed. 4. The scroll compressor of claim 3 , wherein the non-orbiting scroll comprises a non-orbiting wrap forming the compression chambers together with an orbiting wrap of the orbiting scroll, and wherein at least one of the first back pressure hole or the second back pressure hole is formed between outer and inner surfaces of the non-orbiting wrap to be eccentric to one of the outer and inner surfaces. 5. The scroll compressor of claim 3 , wherein the first back pressure hole is formed within a range of a suction start angle to 250°, and wherein the second back pressure hole is formed within a range of 255° to a discharge completion angle. 6. The scroll compressor of claim 3 , wherein the first back pressure valve is slidably inserted into the first back pressure hole to open and close the first back pressure hole, wherein the second back pressure valve is slidably inserted into the second back pressure hole to open and close the second back pressure hole, and wherein the first back pressure valve and the second back pressure valve are symmetrical to each other. 7. The scroll compressor of claim 6 , wherein the first back pressure valve comprises a first valve body that is slidably inserted into the first back pressure hole to close the first back pressure hole, and at least one first communication groove recessed into an outer circumferential surface of the first valve body in the axial direction to communicate with the first back pressure hole, and wherein the second back pressure valve comprises a second valve body that is slidably inserted into the second back pressure hole to block the second back pressure hole, and at least one second communication groove recessed into an outer circumferential surface of the second valve body in the axial direction to communicate with the second back pressure hole. 8. The scroll compressor of claim 3 , wherein at least one of the first back pressure valve or the second back pressure valve is disposed in the non-orbiting scroll. 9. The scroll compressor of claim 8 , wherein the first back pressure valve and the second back pressure valve are disposed in the non-orbiting scroll. 10. The scroll compressor of claim 3 , wherein at least one of the first back pressure valve or the second back pressure valve is disposed in the back pressure chamber assembly. 11. The scroll compressor of claim 10 , wherein the first back pressure valve and the second back pressure valve are disposed in the back pressure chamber assembly. 12. A scroll compressor, comprising: a casing having a low-pressure portion and a high-pressure portion; an orbiting scroll coupled to a rotary shaft in the low-pressure portion of the casing to perform an orbiting motion; a non-orbiting scroll engaged with the orbiting scroll to form compression chambers and movable relative to the orbiting scroll in an axial direction of the scroll compressor; a back pressure chamber assembly disposed at a rear surface of the non-orbiting scroll to form a back pressure chamber; a first back pressure unit disposed between a first compression chamber of the compression chambers and the back pressure chamber to allow movement of a refrigerant from the first compression chamber to the back pressure chamber while blocking reverse movement of the refrigerant, the first back pressure unit comprising a first back pressure valve, the first back pressure valve including a first valve body that is slidably inserted into a first back pressure hole provided between the first compression chamber and the back pressure chamber to close the first back pressure hole, and a plurality of first communication grooves recessed into an outer circumferential surface of the first valve body in the axial direction to communicate with the first back pressure hole; and a second back pressure unit disposed between the back pressure chamber and a second compression chamber of the compressor chambers and spaced apart from the back pressure chamber, to allow movement of the refrigerant from the back pressure chamber to the second compression chamber while blocking reverse movement of the refrigerant, the second back pressure unit comprising a second back pressure valve, the second back pressure valve including a second valve body that is slidably inserted into a second back pressure hole provided between the second compression chamber and the back pressure chamber to block the second back pressure hole, and a plurality of second communication grooves recessed into an outer circumferential surface of the second valve body in the axial direction to communicate with the second back pressure hole. 13. The scroll compressor of claim 12 , wherein the first back pressure unit and the second back pressure unit communicate with compression chambers each having a different pressure. 14. The scroll compressor of claim 12 , wherein the first back pressure unit communicates with the first compression chamber having a relatively lower pressure than a pr