SE467637B - BLOCKING SYSTEM FOR COOLING OR AIR CONDITIONING SYSTEMS - Google Patents

Description

467 637 ra flow of refrigerant from the suction side to the evaporator. A pressure-operated valve (37) is inserted between the condenser and the evaporator (25) to prevent flow of the fluid from the condenser (22) to the evaporator (25) during the standstill of the compressor (21).

A connecting pipe (34) is connected between the valve (37) and the suction side (21a) of the compressor (21) to transfer the pressure from the suction side to the valve. The closing of the valve (37) is controlled by the pressure at the suction side of the compressor (21). When the intake pressure of the compressor (21) exceeds a given predetermined value, it acts on the valve (37) to prevent the flow of refrigerant from the condenser to the evaporator.

This solution has the disadvantage that it can be applied only in refrigeration systems operating with rotary compressors, since this valve (37) is controlled by the pressure in the gaseous refrigerant flowing back through the suction line during the standstill of the compressor (21).

This return of refrigerant gas through the suction line after the compressor has stopped, occurs as a result of the design properties of the rotary compressors. In this type of compressor, the refrigerant gas, which is emitted at high pressure to the housing, leaks through the mechanical unit to the suction side, which power is used to activate the valve (37).

In reciprocating compressors, this effect of refrigerant gas leakage does not occur through the mechanical devices to the suction line, which makes it impossible to use this type of valve in systems with reciprocating compressors.

Another disadvantage of this solution is the large number of welds that must be carried out in the pipelines due to the requirement for at least one more pipe (34) in the cooling circuit. This pipe (34) is required for measuring the pressure in the suction line (21a). The object of this invention is to propose a blocking valve for refrigeration and air conditioning systems, which can be used both in systems with rotary compressors and in systems with piston compressors.

Another object of the present invention is to provide a blocking valve for refrigeration and air conditioning systems which has low energy consumption.

The present invention further aims to provide a blocking valve for cooling and air conditioning systems, which does not require the provision of additional lines in the said systems and thus reduces the number of welds required to a minimum.

The above objects are achieved with a blocking valve for arrangement in a cooling or air conditioning system of a type which essentially comprises a hermetic compressor driven by an electric motor, a condenser and an evaporator connected to the pressure side of the compressor and its suction side, respectively, an intermediate condenser. The control element and the evaporator are arranged control elements of the capillary tube type and a blocking valve arranged between the condenser and the capillary tube. According to the present invention, the blocking valve comprises a housing defining an inner chamber with an inlet opening communicating with the condenser and an outlet opening communicating with the evaporator, a magnetic slide arranged in the chamber in such a way that it can be displaced between an inoperative position in which the inlet opening , and an operative position, where the outlet opening is closed, electromagnetic elements arranged in the housing arranged to be selectively and automatically activated, preferably by the circuit of the electric motor, for a sufficient time to cause displacement of the magnetic slide from one of the arches. the position of the second in accordance with the current supply of the electric motor of the compressor, the retention of the magnetic slide in its inactive position and its operative position being effected by the action of non-electromagnetic forces acting on the magnetic slide at least while maintaining the same in the ove active and the active mode, respectively. In a preferred embodiment of the invention, the housing in which the magnetic slide is arranged consists of two concentrically joined tubular parts. The inner tubular part consists of non-magnetic material and is externally provided with opening and closing windings. The outer tubular part consists of ferromagnetic material and is externally connected to the opening and closing windings, which are attached to the said inner tubular part of the housing. In this preferred embodiment of the invention, the opening winding is connected in series with the starting winding of the electric motor. Consequently, the opening of the valve occurs simultaneously with the start-up of the motor, whereby the opening winding is activated and the magnetic slide is displaced to the opening position.

The retention of the slide in this position takes place through the influence of its own weight.

The valve must therefore be installed in a vertical position. The closing winding is connected in parallel with the motor connection pin (main winding) at the same time as the motor is switched off. The closing of the valve consequently occurs simultaneously with the disconnection of the motor, whereby it acts as a generator during its deceleration, whereby an electric current is caused to appear through the closing winding, which displaces the magnetic slide to the closing position. The retention of the slide in this position is achieved under the influence of the pressure difference between the high-pressure side and the low-pressure side of the system.

The blocking valve thus designed exhibits a very reduced energy consumption, since, unlike the conventional solution (solenoid valve), it does not remain activated during the standstill of the system, but is activated only during the moments when the compressor stops and starts, which corresponds to a fraction of a second. In addition, in the above-described embodiment, the power consumption from the supply system occurs only when the valve is opened, while its closing takes place at the expense of the energy generated by the motor when it is switched off and therefore without any consumption of power from the mains. Another advantage of the blocking valve is that it does not require the installation of any additional pipelines in the system, thus eliminating additional welding operations, which entails increased costs of testing and inspection.

Another advantage that should be mentioned is that this valve is electrically driven, so that it operates independently of the pressures in the system. It can therefore be used both in systems with rotary compressors and in systems with reciprocating compressors. The invention will be described below with reference to the accompanying drawings.

Figure 1 is a schematic representation of a cooling system utilizing a blocking valve according to the invention.

Figure 2 shows a longitudinal section of the blocking valve according to the invention.

Figure 3 shows a section along the line III-III in figure 2.

Figures 4 and 5 show two electrical circuits for the valve together with the compressor starting devices.

Figure 6 shows a variation of the circuit shown in Figure 5. As shown in Figure 1, the cooling system consists essentially of a hermetic compressor 30, a condenser 31, a capillary tube 32 and an evaporator 33. In systems with rotary compressors, a one-way valve 34 is usually (non-return valve) arranged between the compressor 30 and the evaporator 33. The function of this valve is to prevent the flow of the heated refrigerant gas from the housing of the compressor 30 to the evaporator 33 when the system is switched off.

To avoid the flow of refrigerant gas from the condenser 31 to the evaporator 33 through the capillary tube 32 while the compressor is stationary, the system has a blocking valve 40, which in the example shown is arranged between the condenser 31 and the capillary tube 32.

As shown in Figures 2 and 3, the blocking valve 40 consists essentially of a solenoid slide 41 which is movable in a housing 42. The housing 42 is formed by an inner round tubular part 42a and an outer round tubular part 42b, which are concentrically arranged. As shown in the figure, the inner tubular part 42a is externally provided with opening winding 46 and closing winding 47. The outer tubular part 42b is externally connected to the opening winding 46 and the closing winding 47, which are radially attached to the inner tubular part 42a by means of an intermediate ring 48 and a pair of end plates 49a and 49b, which together with the inner tubular part 42a define a chamber within which the slide 41 is movable.

As for the construction of the housing 42, it should be noted that the inner tubular part 42a must be of non-magnetic material, while the outer tubular part 42b, the ring 48 and the discs 49a and 49b must be of magnetic material in order for the magnetic flux to act on the slide 41 in the valve 40 (see the flow lines shown in Figure 2). The housing 42 is connected to the condenser 31 (high pressure side of the system) by means of holes 43 in the disc 49b and to the evaporator 33 10 15 20 25 30 35 42: - O \ * Q CN CN * J (low pressure side of the system) by means of the end 44 of the capillary tube 32.

The magnetic slide 41 is provided with a sealing surface 45, which in the closed position abuts against the end 44 of the capillary tube 32 and blocks the passage of the refrigerant to the evaporator 33. As shown in Figure 3, the magnetic slide 41 preferably has a square cross-section with bevelled edges, so that the slide 41 can be freely displaced between the two positions without compression of the refrigerant in the chamber. Other polygonal_cross-sectional shapes can be used in the design of the slide 41.

The valve is operated by means of the circuits shown in Figures 4, 5 and 6.

As shown in Figure 4, in its preferred embodiment, the electrical circuit for operating the blocking valve 40 consists essentially of a closing winding 47, an opening winding 46 and a two-way switch 50, which is connected to the electric circuit of the motor, which consists of a start winding 51, a starting device 52, a main winding 53 and a power source 54. The motor electrical circuit normally comprises a starting capacitor 55 connected in series with the starting winding 51. The two-way switch 50 is normally actuated by the system thermostat. opening of the blocking valve takes place at the moment when the motor starts, the starting switch 52 allowing a temporary passage of current through the opening winding 46, which is connected in series with the motor starting winding 51. Upon the temporary activation of the opening winding 46, the slide 41 is displaced to the position shown in FIG. 2, i.e. with its sealing end 45 separated from the refrigerant outlet opening or the end 44 of the capillary tube 32, which leads to the evaporator 33. When the engine starting winding is disconnected and thus the opening winding 46, the slide 41 remains in its inactive or valve opening position. 25 30 35 467 637 8 due to the action of its own weight, since the valve is arranged so that its inner chamber is at least approximately vertical. It is provided, however, that the slide 41 can be kept in its inoperative position by the pressure equilibrium between the inlet and outlet openings of the chamber supported by arranging some mechanical means which can exert a weak elastic force on the slide to keep it in an inactive position at all times. .

The closing of the blocking valve 40 occurs at the moment when the motor is switched off, when the two-way switch 50 transitions from position A to position B and connects the closing winding 47 of the valve 40 with the main winding 53 of the motor when the motor is still in deceleration motion. During this deceleration period, the motor acts as a generator and induces a temporary success of a current through the closing winding 47, which is generated by the main winding 53, which causes displacement of the slide 41 by magnetic attraction to the closing position. An alternative embodiment of the electrical circuit for operating the blocking valve 40 is shown in Figure 5. In this circuit, the closing winding 47 is connected in series with a delay device S6 of the PTC (Positive temperature coefficient) type. the opening of the blocking valve 40 takes place in the same manner as described above with respect to the circuit in Figure 4.

The closing of the blocking valve 40 takes place with this alternative embodiment of the circuit after switching off the motor when the two-way switch 57 transitions from position A to position B, so that the power source 54 is connected to the closing winding. When connected to the power source 54, the closing winding 47 is activated and displaces the slide 41 to the closed position. The delay device 56, which f: 10 15 20 25 '30 4 »O \ \ J Ch UI \ 4 in this case consists of a PTC element, means that the current passage in the closing winding 47 is temporary, in that after a certain time the current is reduced to a value significantly lower than the original. A variant of this delay device 56 is shown in Figure 6. This circuit consists of a diode 60 connected in series with a capacitor 61 and with a discharge resistor 62, the capacitor 61 and the discharge resistor being connected in parallel.

Upon cessation of the current supply of the closing winding 47 after the motor has stopped completely according to the embodiment in Figure 4 or after the time specified by the delay device 56 according to the embodiment in Figures 5 and 6, the slide 41 remains in its effective closing position under the influence of the pressure difference that exists between the high-pressure side and the low-pressure side of the system. The outlet opening 44 from the valve chamber is dimensioned so as to ensure the application of a closing force on the slide 41 which exceeds the sum of all forces acting on the slide in such a direction that it would be separated from the closing position as long as the opening winding 46 is deactivated.

It will further be appreciated that the electromagnetic opening and closing forces acting on the slide are selected to ensure displacement of the slide to its respective operating positions, and further that the activation time of these forces is so chosen as to enable the pressure to be reached. state in the system, which corresponds to each of the two working conditions, namely "the compressor in operation" and "the compressor stationary".

Claims (16)

10 15 20 25 30 35 467 657 10 PATENT REQUIREMENTS Blocking valve for refrigeration or air-conditioning systems of the type comprising an f! hermetic compressor driven by an electric motor, a condenser and an evaporator connected respectively to the pressure and suction side of the compressor, a control element of the capillary tube type arranged between the condenser and the evaporator and a blocking valve between the condenser and the control element, characteristic - The blocking valve comprises a housing (42) defining an inner chamber with an inlet opening (43) communicating with the condenser (31) and an outlet opening (44) communicating with the evaporator (33) over the control element (32), a sealing stomach. mesh slide (41) arranged in the chamber so that it can be displaced between an inoperative position or valve opening position and an operative position or valve closing position by sealing the outlet opening (44), electromagnetic elements (46, 47) arranged in the housing (42) ) arranged to be selectively and automatically activated for a sufficient time to cause displacement of the magnetic slide (41) from one working position to the other in accordance with working condition of the system, whereby retention of the magnetic slide (41) in its superior position and operative position is achieved by the action of non-electromagnetic forces acting on the magnetic slide (41) at least during the periods when it remains in the respective working position. Blocking valve according to Claim 1, characterized in that the retention of the solenoid slide (41) in the inactive position or the valve opening position is effected by the action of its own weight. _ Blocking valve according to Claim 1, characterized in that the retention of the magnetic slide (41) in its operative position or valve closing position is effected by means of the pressure difference between the high-pressure side and the low-pressure side. page. l A blocking valve according to claim 1, in that the housing (42) engages an inner tubular part (42a) delimiting the characterized inner chamber, an outer tubular part (42b) "which is concentric with and arranged at a distance from the inner tubular member (42a), a pair of end walls (49a, 49b) closing the two tubular members (42a, 42b), and an intermediate ring (48), the end walls and the intermediate ring radially connecting the two tubular members (42a); , 42b) and the electromagnetic elements (46, 47) are arranged between the two-tubular parts on either side of the intermediate ring. Blocking valve according to claim 4, characterized in that the inner tubular part (42a) consists of non-magnetic material, while the outer tubular part (42b), the end walls (49a, 49b) and the intermediate ring (48) are made of ferromagnetic material. Blocking valve according to one of Claims 1 to 4, the outlet opening (43) and the outlet opening (44) are characterized in that they are arranged in one of the end walls of the chamber. Blocking valve according to Claim 6, characterized in that the outlet opening (44) is formed by the connection of the capillary tube (32) to the interior of the valve chamber. I 1 Blocking valve according to Claim 4, characterized in that the magnetic slide carries a sealing element (45) on its contact surface with the outlet opening (44). 10 15 20 25 30 35 467 637 12 Blocking valve according to Claim 1, characterized in that the activation of the electromagnetic elements (46, 47) takes place by means of the electrical circuit of the compressor motor (30). in) 10. A blocking valve according to claim 9, characterized in that said electric motor comprises a main winding, a starting winding and a starting device, and that the electromagnetic elements consist of a valve opening winding (46), which is connected in series with the electric motor starting winding (51) and starting device (52), so that it is activated simultaneously with the start-up of the electric motor, and a valve closing winding (47) arranged to be activated automatically at the same time as the electric motor is deactivated. Blocking valve according to Claim 10, characterized in that the closing winding (47) is arranged to be automatically connected in parallel with the main winding (53) of the electric motor when it is deactivated, so that it is activated by the current generated by the electric motor. during rotor deceleration. Blocking valve according to claim 10, characterized in that the closing winding (47) is connected in series with a delay device (56), which deactivates the closing winding (47) after a certain period of time has elapsed from the deactivation of the electric motor. Blocking valve according to Claim 12, characterized in that the delay device (56) consists of an element of the PTC type. Blocking valve according to Claim 12, characterized in that the delay device (56) is formed by an electronic circuit consisting of a diode (60) connected in series with a capacitor (61) 10 J: cm »a 13 and with a discharge resistor (62). ), the capacitor (61) and the discharge resistor (62) being connected in parallel. Blocking valve according to one of Claims 10 to 14, the activation of the closing winding (47) is controlled by the feature of a switch (50) arranged in the electric supply circuit of the compressor motor and arranged to be activated automatically depending on a working condition of the system. Blocking valve according to claim 15, characterized in that the operating condition of the system in question is a temperature condition thereof. w ~ <1