Description A COMPRESSOR
[0001] The present invention relates to a compressor comprising a valve plate and which is used in cooling devices.
[0002] In hermetic reciprocating compressors, a considerable amount of the losses incurred in the delivery of the refrigerant gas to the refrigerant cycle occur during the compression of the gas in the cylinder and delivery to the cylinder head discharge volume passing through the opened discharge valve. During the compression stroke of the piston in the cylinder, the gas fills into the discharge chamber of the cylinder head by passing through the discharge passage on the valve plate and the discharge valve at the orifice of the discharge passage that moves by opening and closing and from here is delivered to the refrigerant cycle. The opening movement of the discharge valve is constrained by a stopper situated thereupon. The discharge valve opens as much as allowed by the stopper during the compression of the gas in the cylinder and thus the desired gas pressure is maintained in the discharge chamber. The discharge valve has to open and close in time and at the desired cylinder pressure value in order to prevent the discharge loss that occurs during the passage of the refrigerant fluid into the discharge chamber. The oil in the compressor casing is also present on the surfaces of the discharge valve and the stopper and the discharge valve that contacts the stopper may adhere to the stopper due to the adhesion force of oil and since it can't retract during the suction process in the cylinder, the discharge passage is left open. The refrigerant gas causes discharge loss by passing through the discharge passage, receding back to the cylinder and the compressor capacity is reduced.
[0003] In the United States of America patent document no. US5209260, the explanation is given for the valve unit used in hermetic reciprocating compressors. The discharge valve is mounted within a stepped recess formed in an outer side of the valve plate for opening and closing the discharge passage and, by means of this recess, the length of the discharge passage between the piston dead spot and the discharge chamber is shortened, reducing the amount of gas remaining in this passage before starting the cycle, thus increasing compressor capacity. The movement of the discharge valve is constrained by a bending spring overlying said discharge valve and the movement of the discharge valve and the bending spring is restrained by a stopper member overlying both.
[0004] The aim of the present invention is the realization of a compressor wherein the per-
formance of the valves situated on the valve plate is improved.
[0005] The compressor realized in order to attain the aim of the present invention is explicated in the claims.
[0006] In compressors, the refrigerant fluid is sucked and pumped by a piston moving in the cylinder and is delivered from the suction chamber to the cylinder and to the discharge chamber from the cylinder by means of the opening, closing of the suction and exhaust valves disposed on the valve plate situated between the cylinder and the cylinder head. The movement of the discharge valve during opening is constrained by a stopper mounted on the valve plate.
[0007] In the embodiment of the present invention, the contact area between the stopper and the discharge valve is decreased, reducing the adhesion effect particularly due to the oil therebetween and providing the exhaust valve to close by preventing it from remaining adhered to the stopper when it has to close.
[0008] In the preferred embodiment of the present invention, cut-outs are provided on the stopper decreasing the contact area of the discharge valve. In this embodiment, the discharge valve, when opened, only contacts those surfaces excluding the cut-out and the adhesion force is reduced.
[0009] Furthermore, the contact of the upper surface of the discharge valve with the high pressure gas in the discharge chamber is provided by means of the cut-out formed on the stopper, thus gas pressure acts on the upper surface of the discharge valve decreasing the pressure imbalance between the two surfaces of the discharge valve and providing easier opening and closing.
[0010] In another embodiment of the present invention, the stopper comprises protrusions that decrease the contact area of the discharge valve, providing the discharge valve, when opened, to only contact the ends thereof. In this embodiment, when the discharge valve opens, it only contacts the ends of the protrusions on the stopper thus reducing the adhesion force.
[0011] The compressor realized in order to attain the aim of the present invention is illustrated in the attached figures, where:
[0012] Figure 1 - is the cross-sectional view of a compressor.
[0013] Figure 2 - is the exploded view of a valve plate, the suction and exhaust valves and a stopper.
[0014] Figure 3 - is the perspective view of a valve plate, and a discharge valve and stopper mounted on the valve plate.
[0015] Figure 4 - is the schematic view of a valve plate situated on a cylinder and the
suction and exhaαst valves and a stopper thereon. [0016] Figure 5 - is the schematic view of a valve plate situated on a cylinder and the suction and exhaαst valves and a stopper thereon in another embodiment of the present invention. [0017] Figure 6 - is the detailed schematic view of the stopper and the discharge valve in the embodiment in Figure 5. [0018] Figures 7, 8, 9, 10 - are the perspective views of stoppers having cut-outs of various shapes. [0019] The elements illustrated in the figures are numbered as follows:
1. Compressor
2. Casing
3. Cylinder
4. Piston
5. Cylinder head
6. Valve plate
7. Suction chamber
8. Discharge chamber
9. Inlet passage
10. Discharge passage
11. Suction valve
12. Discharge valve
13. Stopper
14. Cut-out
15. Protrusion
[0020] In cooling devices, for example refrigerators, the circulation of the refrigerant fluid is provided by a compressor (1).
[0021] The compressor (1) comprises a casing (2) wherein the components within are held, a cylinder (3) for pumping the refrigerant fluid, a piston (4) operating in the cylinder (3) a cylinder head (5) providing the circulation of the refrigerant fluid sucked and pumped by the reciprocation of the piston (4) a valve plate (6) disposed between the cylinder (3) and the cylinder head (5) a suction chamber (7) under the cylinder head (5) wherein the sucked refrigerant is accumulated, a discharge chamber (8) wherein the pumped refrigerant fluid accumulates, an inlet passage (9) and a discharge passage (10) situated on the valve plate (6) providing entry and exit of the refrigerant fluid in the suction and discharge chambers(7, 8) into/from the cylinder (3).
[0022] The compressor (1) furthermore comprises a suction valve (11) situated on one side of the valve plate (6) that opens and closes the inlet passage (9) during the reciprocation of the piston (4) providing the refrigerant fluid to be aspirated into the cylinder (3) and a discharge valve (12) on the other side of the valve plate (6) that opens and closes the discharge passage (10) during the reciprocation of the piston (4) providing the refrigerant fluid to be discharged from the cylinder (3).
[0023] The oil put into the casing provides the components in the compressor (1) to move with ease.
[0024] The compressor (1) of the present invention comprises a stopper (13) that
- is situated on the discharge valve (12) at the valve plate (6)
- allowing the discharge valve (12) to open to a little extent by restraining the movement and thus maintaining the desired pressure in the discharge chamber (8) and
- has one or more cut-outs (14) providing to reduce the surface area that the discharge valve (12) contacts.
[0025] The cut-out (14) is preferably shaped like a hole bored on the stopper (13) having various sizes (Figures 7, 8, 9, 10).
[0026] The cut-out (14) is made by hollowing out a part on the stopper (13) by perforating or drilling process.
[0027] When the discharge valve (12) opens, it impacts on the surfaces of the stopper (13) excluding the cut-outs (14) and contact is maintained on the surface of the stopper (13) in an area less than the area of the discharge valve (12). Consequently, the adhesion force effect of the oil between the discharge valve (12) and the stopper (13) is reduced, minimizing the thermodynamic losses that occur in the discharge phase of the refrigerant cycle.
[0028] When the piston (4) makes the compression stroke in the cylinder (3) the discharge valve (12) opens contacting the stopper (13) and when the piston (4) is in the sucking stroke, the discharge valve (12) released from the stopper (13) closes the discharge passage (10) in time since the contact surface therebetween is reduced due to the cutouts (14) and accordingly the discharge gas leakage is prevented. The refrigerant fluid pumped into the discharge chamber (8) is not aspirated back into the cylinder (3) again and the compressor (1) capacity is enhanced since the discharge passage (10) is closed in time during the suction process of the refrigerant fluid pumped into the discharge chamber (8).
[0029] By means of the cut-outs (14) formed on the stopper (13) the upper surface of the
discharge valve (12) is furthermore provided to come into contact with the high pressure gas in the discharge chamber (8). Accordingly, gas pressure acts on the upper surface of the discharge valve (12) and the pressure imbalance between the two surfaces of the discharge valve (12) is reduced providing easier opening and closing.
[0030] In the compressor (1) the rotational movement of the motor is transmitted to the piston (4) by means of the crank-connecting rod mechanism providing the recip- rocative movement of the piston (4). By the movement of the piston (4) the process of sucking of the refrigerant fluid to/from the cylinder (3) is provided. The refrigerant fluid entering the cylinder (3) by means of the inlet passage (9) on the valve plate (6) and by the opening, closing suction valve (11) is compressed to maintain the desired pressure. The refrigerant fluid is delivered into the discharge chamber (8) by means of the discharge passage (10) on the valve plate (6) and the opening, closing discharge valve (12). When the discharge valve (12) opens and closes, the movement is restrained by the stopper (13) and the refrigerant fluid with the desired pressure is collected in the discharge chamber (8). The discharge valve (12) is released from the stopper (13) by retracting, closing on the discharge passage (10) just as the piston (4) starts the suction stroke by retracting and the refrigerant fluid in the discharge chamber (8) is prevented from receding back into the cylinder (3).
[0031] In another embodiment of the present invention, the stopper (13) comprises one or more protrusions (15) that reduces the contact area of the discharge valve (12) thus providing the discharge valve (12) when opened, to only contact the ends thereof. In this embodiment, the discharge valve (12) when opened, only contacts the protrusions (15) on the stopper (13) and the adhesion force is reduced.
[0032] In this embodiment, more than one cut-out (14) is formed on the surface of the stopper (13) contacting the discharge valve (12) and the protrusions (15) are arranged between the cut-outs (14) (Figure 6).
[0033] In the embodiment of the present invention, the contact area between the discharge valve (12) and the stopper (13) is reduced by means of the cut-out (14) and/or the protrusion (15) formed on the stopper (13). By means of reducing the contact area between the discharge valve (12) and the stopper (13) the adhesion force due to the oil therebetween is reduced in direct proportion. By means of reducing the adhesion force, the closing time of the discharge valve (12) is expedited and the compressed gas in the discharge chamber (8) is prevented from receding back into the cylinder (3) volume. A significant increase in the efficiency of the compressor (1) is provided by reducing the losses incurred in the delivery of the refrigerant gas, compressed to a certain pressure
value in the cylinder (3) volume, to the cylinder head (5) discharge chamber (8).