NL8304420A - COOLING OR HEAT PUMP SYSTEM. - Google Patents

Description

'* ^ V * 9 PHN 10.887 1'. -. ! N.V. Philips * Incandescent light factories in Eindhoven. .

Cooling or heat pump system. -------

The invention relates to a cooling or heat pump system with an evaporator, a compressor, a condenser and a throttle, the compressor being an electric motor and a piston cmp, which piston cmp cylinder, in which a piston driven by the electric motor moves to influence a compression space located above the piston, the compressor being provided with an inlet and an outlet, which pipes are connected to the evaporator and the condenser, respectively, and furthermore, an adjoining space is provided, which can be connected to the compression space by means of control of a closing element, the compression space and the adjoining space.

Most cooling or heat pump systems are controlled by an on / off control of the compressor. Various control options are known in order to increase the efficiency of such a system by means of continuous operation, ie continuously running compressor. For example, by speed control of the electric motor of the compressor. This arrangement is good in itself, but very expensive. A control is also known in which different small compressor units are used and, depending on the capacity requirement, one or more compressors can be switched off. This arrangement is only worthwhile if the capacity of the system is sufficiently large. Another known possibility is the harmful space control, wherein an additional harmful space, a so-called switching space, is added to the normally present compression space depending on the required capacity.

The invention relates to a system with a control according to the latter method. It is known that a connection between the compression space and the switch space is provided by means of a pneumatic or a manually controlled valve.

The object of the invention is to increase the efficiency of the system by means of a simple and inexpensive control.

To this end, the system according to the invention is characterized in that the closing member is electromagnetically controlled and the system is a 8304420 r PHN 10.887 2 / *. · _.

+ - 'ï contains a control which reduces the power of the electric motor when switching the switch room.

A consequence of a harmful moulting regulation is that the amount of circulated refrigerant mass is smaller, as a result of which the evaporation temperature is higher and the condenser temperature is lower and consequently the carburizing work is reduced. On average, cold is now generated at a lower temperature than with an on / off controlled system. In other words, in the system according to the invention, the cold is generated at a higher efficiency. However, during the period when the auxiliary switching space is added to the compression space, the compressor does not have to pump as much mass, which reduces the required torque of the electric motor and reduces the efficiency. In order to maintain the efficiency of the electric motor at the same level, the power is reduced during the said period. To generate the same amount of cold qp as in an on / off controlled system, the combined control of the system according to the invention results in a net less energy consumption of about 10%.

A preferred embodiment is characterized in that the compressor is provided with a cover, in which the switch compartment is located, which is connected by means of a connecting channel to the compression groove, the closing member is coupled to the core of the electromagnet, which closing member is energizing the solenoid opens the connecting channel and closes if not energized by a return spring. This has the advantage that if the control is refused, for whatever reason, the return spring places the shut-off element in the position where the maximum capacity of the compressor is switched on, in which case a normal on / off control is switched on.

A further preferred embodiment is characterized in that the compressor is provided with a valve plate located between the cover and the cylinder, which valve plate is provided with a bore in which the closing member can be slid and with the said connecting channel which cuts the bore, which closing member is provided with a piercing, such that when the electromagnet is energized it is in line with the connecting channel. The advantage of this is that during the energization of the electromagnet due to the compression pressure no varying force is exerted on the closing member.

It is favorable for the efficiency of the system that the resistance of the throttling member is increased during the switching of the space at switch 8304420.

The invention will now be further elucidated on the basis of an exemplary embodiment shown in drawings.

Fig. 1 shows the cooling or heat pump system; FIG. 2 is a partial cross section of the compressor;

Fig. 3 is a cross-sectional view of the compressor taken on the line III-III of FIG. 2;

Fig. 4 shows cost effective torque curves of the electric motor;

Fig. 5 shows the electrical circuit of the system; FIG. 6 shows the temperature behavior of the evaporator and the condenser;

Fig. 7 shows a cooling system with resistance adjustment of the capillary.

The system consists of a evaporator 1, a compressed air 2, a condenser 3 and a smoar valve 4, which are connected in a closed cycle by means of pipes. The compressor is closed by a hermetically closed housing 5, in which there is an electric motor 6 and a piston pot 7. The piston pcp comprises a cylinder 8, which contains a piston 9 driven by the electric motor, a cover 10 and a valve plate 11 located between the cover and the cylinder. The valve plate is provided with an inlet port 12 with an inlet valve 13 and outlet ports 14 with outlet valves 15. The housing 5 of the compressor is provided with an inlet 16 and an outlet 17, which are connected by means of lines with the evaporator 1 and the condensation -25 sor 3 are connected. The coolant suction gas is drawn into the compression chamber 19 through the suction chamber 18 and inlet port 12, then compressed and forced back into the system through outlet port 14 and bale chamber 20.

According to the invention, in order to control the system, the piston pump 7 is provided with a switching space 21. The valve plate 11 30 is provided with a connecting channel 22 which connects the switching space 21 with the compression space 19. In the valve plate 11 there is a bore 23, into which a closing member 24 can be slid. The bore 23 intersects the connecting channel 22. The closing member 24 is integral with the movable core 25 of an electromagnet 26. The core 25 contains a coil 27 which is integrated in an electrical control of the system. The electromagnet also has a return spring 28.

The pin-shaped closing member 24 is provided with a bore 29, which, depending on the position of the closing member, may or may not be aligned with the connecting channel 22 and thus opens or closes the connecting channel. . In the drawn position of fig. 2, the electromagnet 26 is energized and the piercing 29 is aligned with the connecting channel 22, so that the switch space 21 is added to the body space 19. The compressor then operates at a reduced capacity. It is favorable in this position that the compression pressure acts on all sides (¾) on the wall of the bore 29 of the closing member 24, so that no resulting forces act on the closing member, which would otherwise have to be compensated by the force of the electromagnet. When the electromagnet is not energized, the return spring 28 pushes the closing member to the left, whereby the connecting channel is closed.

In this mode, the compressor operates at maximum capacity (Fig. 3). Preferably, the switch room 21 is insulated from the environment, so that no additional heat losses occur.

The invention also comprises a control which reduces the power of the electric motor during switching of the switch compartment 21. Fig. 4 shows two efficiency circuits of the electric motor. In curve I, the motor operates at a higher power than in curve II. During the period that the compressor operates without a switch-on space of 20 °, the working area of the electric motor lies between the points A and B of curve I. If the switch room 21 is now connected to the compression room 19, the torque T will decrease. and consequently also the efficiency. The electric motor will then work, for example, between points C and D. By lowering the power now, the efficiency can be increased again. The electric motor then operates, for example, in the yield-favorable region E-F of curve II. Reduction of torque adjustment power is preferably achieved by using a lossless power controller. As an example of this, a transformer could be used to reduce the voltage. However, a transformer is expensive. Cheaper is also the lossless power regulator 30, which is shown in FIG. 5 is shown. In the network consisting of two different resistors and (R ^ <R2), a capacitance C, a diac D, a triac T and a voltage-dependent resistor VDR, depending on the position of the switch S1, a different phase-to-35 cut is made. the mains sine. The position of switch S1 is determined by an adjustable thermostat 31. At a maximum evaporator temperature (for example -3 ° C), the switch SI is set to the right position (full power) and at an adjustable minimum evaporator temperature 8304420 ΕΗΝ 10.887 5 · '·' '' "-" (ί Λ (for example -16 to -24 ° C) in the left position (reduced power) cm. If the compressor is running at full power (SI in the right position), the switch S2 is open and the coil 27 of the electromagnet 26 is not energized for the operation of the shut-off member 24. On the other hand, with reduced power output, switch S2 is closed, the electromagnet energized, so that the shut-off member 24 connects the connecting channel 22 between the switching space 21 and the Compression area 19 opens,

In FIG. 6 shows the temperature behavior of the evaporator and the condenser, both for a known on / off control and for the two-position control according to the invention. The temperatures shown are measured on the coolant side. The dashed lines relate to the on / off control and the solid line newspapers relate to the control according to the invention. With the 15 on / off control, the condenser temperature during the on-period of the compressor ranges from 25 ° C (ambient temperature) to approx. 50 ° C (a1), while in the same period the evaporator temperature of 9 ° C (refrigerator temperature) drops to -24 ° C (b1). In the subsequent standstill period, the condenser temperature drops to about 25 ° C (a2) and the evaporator temperature rises to about 9 ° C (t> 2). This control causes a temperature fluctuation (c) in, for example, the cooling space (air) of a refrigerator of approx. 8 ° C. With the new two-stage control, the condensing temperature during the short period of full compressor capacity ranges from approx. 32 ° C to approx. 45 ° C (d1), while the evaporating temperature in the same period from -5 ° C to -20 ° C (e1) drops. In the subsequent long period with reduced compressor capacity, i.e. with the addition of the switching space and reduced drive voltage, the condenser temperature drops again to about 32 ° C (d2) and the evaporator temperature rises to about -5 ° C ( e2). The temperature changes of the evaporator and the condenser are much smaller with the new control. The consequence of this is that the temperature variation (f) in, for example, the cooling space (air) of a refrigerator is also much smaller (approx. 3 ° C).

Since during the switching-on period of the switching-on space 21 the mass flow of the coolant is smaller, in order to maintain the pressure drop the resistance of the smoother member 4 will have to be greater. For a cooling system, in which a capillary is used as the smoother, is in Pig. 7 shows an example of how the resistance can be adjusted in two positions. In the circuit, two ca 8304420 * ΐ ΕΗΝ 10.887 6 "-pillars 4a and 4b are connected in series, during which the capillary 4a is short-circuited by opening the valve 32 during full power of the compressor. At reduced power the valve is closed and both capillaries are active Preferably, the valve 32 is operated electromagnetically 5. Fig. 5 shows the position where the solenoid valve is indicated by a broken line in the circuit At reduced power, switch S3 is closed, the coil 33 of the electromagnet is energized and the valve 32 closed.

A temperature-controlled expansion valve is often used with heat pumps. The expansion valve automatically receives the correct holes for maintaining the pressure drop.

15 -20 25 30 35 8 304 420

Claims (4)

1. Cooling or heat pump system with an evaporator (1), a catrr pressor (2), a condenser (3) and a smoother (4), the compressor being an electric motor (6) and a piston pump (7), the piston pump comprising a cylinder (8) in which a piston (9) driven by the electric motor moves to influence an compression outlet (19) located above the piston, the compressor being provided with an inlet (16) and an outlet ( 17), which are connected by means of pipes to the evaporator and the condenser, respectively, and furthermore are provided with a switching space (21), which can be connected to the compression space (19) by control of a shut-off valve ( 24) between the compression space and the switch-on space, characterized in that the shut-off device is electromagnetically controlled and the system comprises a control (30) which reduces the power of the electric motor when the switch-on space (21) is switched on. Cooling or heat pump system according to claim 1, characterized in that the compressor (2) is provided with a cover (10), in which the switch-on space (21) is located, which is connected by means of a connecting channel (22). is connected to the compression space (19), the sealing member (24) is coupled to the core (25) of the electromagnet (26), which sealing member opens the connecting channel (22) when the electromagnet is energized and, if not energized, by a return stop adjusting spring (28). A cooling or heat pump system according to claim 1 or 2, characterized in that the compressor (2) is provided with a valve plate (11) located between the cover (10) and the cylinder (8), which valve plate is provided with a bore (23), in which the closing member (24) is slidable and of said connecting channel (22), which intersects the ring (23), which closing member (24) is provided with a bore (29), such that upon actuation of the electromagnet (26) in line with the connecting channel (22). Cooling or heat pump system according to any one of the preceding claims, characterized in that the resistance of the switch (4) is increased when the switch-on space (21) is switched on. 35 8304420