PL28876B1 - Gebriider Zehnder Radiatoren & Apparatenbau, Granichen. The refrigerator is completely self-acting. - Google Patents

Description

In the hitherto known fully automatic refrigerators, the compressor piston is forced by external force both during the compression stroke and during the return stroke, and in the event of interruptions in the refrigerant circuit, the drive must be turned off and on again. According to the present invention, the compressor piston is externally driven only during the compression stroke, while on the return stroke it is driven by the refrigerant vapor flowing into the compressor cylinder. In this way, the energy consumed by the refrigerator can be reduced, since the compressor's operation then automatically adjusts to the instantaneous energy demand of the refrigerator, and this is due to the fact that, with a low demand for winter for the compressor piston, it makes its strokes relatively rarely. however, with high cold demand, the compressor's piston stroke rate becomes greater. In addition, the piston drive is automatically interrupted in the event of a break in the refrigerant circuit, since the piston is then not forced back into the refrigerant vapor. The number of parts that could interfere with the operation of the compressor is thus considerably reduced, and therefore not possible. The drive mechanism is greatly simplified, so that the costs of making a cooler and the costs of maintaining it in operation are correspondingly lower. There are already known coolers with fully automatic operation, in which the compressor piston is driven by an electromagnet. In one such known arrangement the return stroke of the piston is caused by the action of a spring, the spring having to be tensioned with each compression stroke. A separate rotary chopper is used to switch the magnetizing current on and off, which determines the speed of its movement by the number of strokes of the piston per unit time. Here, the refrigerant vapor is introduced into the cylinder on the rear side of the piston, from which it flows during the reverse stroke through a piston bore provided with a reverse valve, into the working space, and during the reverse stroke the pressure exerted by the refrigerant, acts on the piston against its movement. In another known refrigerator, two electromagnets are used to induce the power stroke and reverse stroke, which are actuated by the compressor piston at its extreme positions. As a result of the successive switching on and off of the electromagnets, the compressor piston moves rapidly and without interruption with a reciprocating motion, which, as when driven by an electric motor, achieves a uniform piston drive. In the case of a cooling unit, such a drive is however, it is pointless, since the power requirement of a refrigerator varies greatly with the outside temperature and the heat input. For example, if a refrigerated chamber is opened several times in a short time, the temperature in the refrigerator may rise quite significantly, so that with a uniform drive of the refrigerator, a longer period of time is required to cool the inside of the refrigerator to normal temperature * Such a device is quite complicated due to the use of two electromagnets. The present invention avoids these drawbacks by the fact that the electromagnet driving the piston switches off by the plunger before it is actuated by the reverse stroke and is then switched on again afterwards. With this design of the refrigerator, only one solenoid is required to drive the piston, which does not need to be brought into the original position by means of a spring. The figure shows a schematic embodiment of the invention. Number 1 denotes a compressor cylinder in which piston 2 moves and is provided with an inlet valve 3 and an outlet valve. The outlet valve k is connected by a line 5 to a coil 7 located in the condenser 6, which at the other end is connected to the evaporator 10 via a line 8 provided with a control valve 9. The refrigerant evaporates in the evaporator 10 and receives it. thus the heat from the refrigerated chamber 11. The conduit 12 leads the refrigerant vapor from the evaporator 10 to the valve 3 of the compressor. The piston rod 13 extends outside the cylinder 1 and is connected to the arm of the toggle lever li, pivotally mounted on the axis 15. The other arm of the lever lk is connected by means of a rod 16 to an anchor 17 which is attracted by an electromagnet 18. One the end of the winding 19 of this electromagnet is connected by a conductor 20 to the conductor Lx of the AC network. The other end of the winding 19 is connected by a conductor 21 via a switch 22 and also a switch 23 to a conductor L2 of the same AC mains. The switch 22 is closed by the outer end of the piston 13, while the switch 23 is closed by means of a toggle lever A k * A rod 25 is attached to the anchor 17, which, when the anchor 17 is fully drawn, tilts the toe lever 2i causes the opening of the switch 23. - 2 - In the position of the individual parts of the device shown in the figure, the circuit of the winding 19 of the electromagnet is closed by the switch 23. The electromagnet 18 then attracts the anchors 17 and thus engages with the rod 16 and the toggle lever 14 the piston 13 is moved to the right. The piston 2 forces the refrigerant contained in the compressor cylinder 1 into the condenser 0. When the anchor 17 is fully drawn, the piston is in its extreme position, with the lever turning The tube 2U is turned so that the switch 23 opens. As a result, the current in the winding 19 is interrupted and the piston 2 moves under the pressure of the vapor of the refrigerant. it, returning from the evaporator 10 through the valve 3. In the extreme left position of the piston 2, the piston rod 13 closes the switch 22, which restores the current flow to the winding 19. The magnet 18 then attracts the anchors 17, and at the same time the toggle lever 24. By pulling the lever 24, the circuit breaker 23 closes so that during the compression stroke the circuit of the winding 19 remains closed by the circuit breaker 23, although the circuit breaker 22 opens at the beginning of the stroke. If the flow of the refrigerant circuit in the refrigerator is momentarily Due to the throttling of the temperature control device, the piston 2 will not move back and the compressor drive will be automatically interrupted, so that it is not necessary to use separate devices to interrupt this drive. Instead of an electromagnet, it is also possible to use a piston, for example a water motor as a source of external force to actuate the compressor piston. PL

Claims (3)

Patent claims. 1. A fully automatic refrigerator having a cylinder connected by a pipe to the evaporator, a piston which acts on the drive during its movements, characterized in that the indicated drive device is made such that it is brought into a state by the piston. active at the end of the suction stroke of said piston, and turned off - after the end of the compression stroke of said piston. 2. Refrigerator according to claim 1, characterized in that an electromagnet (18) is used as the driving force, in the circuit of which there are built-in contact devices for switching it on during the compression stroke and switching it off at the suction stroke, effected by the expansion of the refrigerant, including the cylinder itself. 3. Refrigerator according to claim 2, characterized in that the contact device (22) is connected to the circuit (19) at the end of the suction stroke, initiating only compression, during which the piston rod (13), moving to the right, switches the contact off (22), the current flows through a second contact device (28) which was also switched on at the end of the suction stroke. Gebriider Zehnder Radiatoren & Apparatenbau. Deputy: engineer W. Zakrzewski, patent attorney. PRINT M ARCT CZERNIAKOWSKA 225 To the patent description No. 28876 PL