JP2818445B2 - Blocking valve for cooling or air conditioning system - Google Patents

Description

The present invention relates to a blocking valve for a cooling or air conditioning system.

[Prior art Cooling and air conditioning systems consist essentially of a compressor, a condenser, a capillary and an evaporator.

In these systems, movement of the heated fluid from the condenser side (high pressure side) to the evaporator (low pressure side) occurs when the temperature of the evaporator reaches a predetermined value and the compressor is turned off. When the normal operating cycle of the system is reset, i.e. when the pressure and temperature levels are reset in each unit of the system, the compressor must be stopped because the coolant must be recompressed each time the compressor is restarted. This transfer of coolant to the evaporator at times results in a loss of cooling capacity in the system (about 6% in systems using reciprocating compressors and 12% in systems using rotary compressors).

A first known method of solving this problem involves the use of a solenoid valve provided between the condenser and the capillary. In this cooling cycle, the valve is energized at the same time as the condenser (rotary compressor) stops,
Prevents coolant from flowing into the evaporator from the condenser.

The problem with this solution is that the valve remains energized during the shutdown of the refrigeration system, and consequently also during the shutdown of the compressor, during which time a considerable amount of It consumes energy.

Another known solution is the UK patent GB 212 1942 A
It is described in the specification. The system includes a one-way valve mounted between the suction side of the compressor and the evaporator to prevent coolant from entering the evaporator from the suction side. A pressure-responsive valve is provided between the condenser and the evaporator to prevent the flow from the condenser to the evaporator during the stop period of the compressor. A connecting tube is connected between the valve and the suction side of the compressor for transmitting pressure from the suction side to the valve. The closing of the valve is controlled by the suction pressure from the compressor. When the compressor suction pressure becomes greater than a predetermined predetermined value, it acts on the valve to block the passage of coolant flow from the condenser to the evaporator.

This solution has the inconvenience that it can only be applied to cooling systems that use rotary compressors, because this valve is controlled by the pressure of the coolant gas returning through the suction line during the compressor shutdown period. There is.

The return of the coolant gas through the suction line after the compressor shuts down occurs due to the structural characteristics of the rotary compressor. In this type of compressor, the coolant gas released into the housing at high pressure leaks from the machine to the suction side. This effect is used to activate the valve.

In a reciprocating compressor, this effect of coolant gas leakage from the mechanical device to the suction line does not occur, and therefore valves of this type cannot be used in systems using reciprocating compressors.

Another inconvenience of this solution is the number of welds performed during piping due to the need for at least one additional tube in the cooling circuit. This tube is needed to measure the pressure in the suction line.

It is an object of the present invention to provide a cooling device that can be applied to both a system using a rotary compressor and a system using a reciprocating compressor.

Another object of the present invention is to provide a cooling device with low power consumption.

It is yet another object of the present invention to provide a cooling device that does not require additional piping in the device and thus minimizes the number of welding operations.

[Means for Solving the Problems] According to the present invention, the above-mentioned problems are solved by a compressor,
An element disposed outside the guide chamber for generating an electromagnetic force between a capacitor and a release position and a sealing position disposed inside the guide chamber and remote from an outlet opening of the guide chamber; A valve control means having an electromagnetic slide (41) movable by and capable of holding the release position and the sealing position by a force other than an electromagnetic force. Said guiding chamber constitutes a valve chamber (42) of a blocking valve (40), which is connected to said condenser (31) via an inlet opening (43) and said outlet opening (4).
4) is connected to an evaporator (33) on the suction side of the compressor (30), and the electromagnetic slide (41) is in its sealed position in the valve chamber (4).
2) The outlet opening (44) is sealed, and the entrance opening (4
This is achieved by a blocking valve, characterized in that it is held in a sealed position by a pressure difference acting between 3) and said outlet opening (44).

[Operation] According to the above-described blocking valve of the present invention, the sealed electromagnetic slide is selectively and automatically moved by the electromagnetic element for a time sufficient to move the electromagnetic slide from one operating position to the other operating position. The activation of the electromagnetic slide and the maintenance of the state of the electromagnetic valve in the operating position or the non-operating position of the electromagnetic slide are performed by the action of the non-electromagnetic force acting on the electromagnetic slide at least during the period in which each operating position is maintained.

In the present invention, the flow path is provided inside the housing and allows the pressurized fluid supplied from the condenser to pass through the evaporator, and the magnetic material opens the flow path when the air compressor is driven and opens the flow path when the air compressor is stopped. Since the pressure is maintained in the flow path by the pressure of the pressurized fluid so as to close, the supply and stop of the pressurized fluid to the evaporator can be performed reliably and smoothly regardless of the type of air compressor used, and the operation of the cooling device Can start and stop the cooling action efficiently and quickly.

In an embodiment of the invention, the blocking valve is a housing defining an interior chamber by an inlet opening for communication with the condenser and by an outlet opening for communication with the evaporator, and a non-operative position for maintaining the inlet and outlet openings open. A magnetic body or sealed magnetic slide mounted inside the chamber so that it can be moved between the operating position to seal the outlet opening and an energizing motor of a compressor provided in the housing. Including an electromagnetic element that is selectively and automatically activated, preferably by an electric motor circuit, during a period sufficient to move the magnetic slide from one operating position to another, and holding the magnetic slide in a non-operating and operating position Is a non-electromagnetic that acts on the magnetic slide during at least the non-operating and maintaining positions of the magnetic slide It is carried out by the action of.

In a preferred embodiment of the present invention, the housing provided with the magnetic slide comprises two concentric tube sections. The inner tube section is made of a non-magnetic material and is provided with open and closed coils on the outside. The outer tube section is made of ferromagnetic material and is formed outwardly with respect to the open and closed coils and is fixed to said inner tube section of the housing.

Furthermore, the open coil is connected in series with the start winding of the electric motor. As a result, the valve is opened simultaneously with the start of the motor, at which moment the open coil is energized and the magnetic slide is moved to the open position. The maintenance of the magnetic slide in this position is caused by the action of its own weight.

Therefore, the valve must be positioned vertically. The closed coil is connected in parallel with the motor terminal (main winding) at the same time as the motor is turned off. As a result, the closing of the valve occurs at the same time as the motor is turned off and moves the magnetic slide to the closed position when the motor operates as a generator during its deceleration period to generate current circulating through the closed coil. Retention of the magnetic slide in this position is provided by the pressure difference between the high and low pressure sides of the system.

The blocking valve so configured is only activated for a fraction of a second when the compressor is stopped and started, rather than being activated during a system shutdown, for the usual solution. , Indicating a greatly reduced power consumption.

In the above structure, the current consumption of the power supply system occurs only at the moment when the valve opens, and the closing is performed at the moment when the motor is turned off, using the power generated thereby, without consuming the current from the power supply system. .

Another advantage of embodiments of the present invention is that no additional plumbing is required in the system, thus eliminating the need for additional welding operations that are expensive with respect to testing and control.

Another advantage is that the valve is electrically actuated and thus operates independent of system pressure. This is why it can be provided in systems that use both rotary and alternative compressors.

EXAMPLE As shown in FIG. 1, the cooling device or system consists essentially of a sealed air compressor 30, one condenser 31, one capillary tube 32 and one evaporator 33. . In a system using a rotary compressor, a one-way valve 34 (check valve) is usually provided between the compressor 30 and the evaporator 33. The function of this valve is to move the evaporator 33 from the housing of the compressor 30 at the moment of system shutdown.
To block the flow of the heated coolant gas to the air.

To prevent the flow of coolant gas from the condenser 31 through the capillary 32 to the evaporator 33, during a compressor shutdown, the system may for example be a blocking valve mounted between the condenser 31 and the capillary 32 as shown. Use 40.

As shown in FIGS. 2 and 3, the blocking valve 40 consists essentially of a magnetic slide 41 that moves inside a housing. The housing 42 is formed by an inner circular tube portion 42a and an outer circular tube portion 42b that are assembled concentrically. As shown in the drawing, the inner tube part
42a has an open coil 46 and a closed coil 47 externally. The outer tube portion 42b is configured outwardly with respect to the open coil 46 and the closed coil 47 and is radially secured to the inner tube portion 42a by an intermediate ring 48 and a pair of end disks 49a and 49b. 49b is the inner tube part 42
With a, the chamber in which the slide 41 shifts inside is limited.

From a structural point of view of the housing 42, the inner tube portion 42a must be a non-magnetic material, while the outer tube portion 42b, the intermediate ring 48 and the discs 49a and 49b allow the magnetic flux to act on the slide 41 of the valve 40. (See the flow path shown in FIG. 2). housing
42 is connected to the condenser 31 (high pressure side of the system) by holes 43 formed in the disc 49b, and to the end of the capillary 32
It is connected by 44 to an evaporator 33 (low pressure side of the system).

The magnetic slide 41 is located on the end 44 of the capillary 32 in its closed position and is provided with a sealing surface 45 which closes the flow path of the coolant to the evaporator 33. As shown in FIG. 3, the magnetic slide 41 has a square cross-section with edges cut out so that it can slide freely between the two positions without compressing the coolant fluid in the chamber. It is preferred to have. Other polygonal cross sections may be applied in the structure of slide 41.

The valve is operated by the circuits shown in FIGS. 4, 5 and 6.

According to FIG. 4, the electric circuit for the operation of the blocking valve 40 comprises a start winding 51, a start device 52, a main winding 53 and a power supply.
Closed coil 47, connected to the electric circuit of the motor consisting of 54,
The open coil 46 and the two-way switch 50 constitute essentially its preferred form.

The electric circuit of the motor usually includes a start capacitor 55 connected in series with the start winding 51. 2-way switch 50
Is usually operated by a system thermostat.

The opening of the blocking valve occurs at the moment of start of the motor, where the start switch 52 allows temporary current circulation through the open coil 46 connected in series with the start winding 51 of the motor.

The temporary bias of the open coil 46 moves the slide 41 to the position shown in FIG. That is, its sealed end 45 is separated from the coolant fluid outlet opening or end 44 of the capillary tube 32 connected to the evaporator 33. When the motor's start winding and thus the open coil 46 are de-energized, the slide 41 is configured by its own weight to be in its inactive or valve open position because the valve is configured to have its internal chamber at least approximately vertically positioned. It is located as it is. However, the slide 41 is held in its inoperative position only by pressure equilibrium at the inlet and outlet openings of the chamber, and a small elastic force can be used to move the slide 41 lightly and consistently to the inoperative position. It should be understood that any mechanical equipment can be supported. Blocking valve
The closing of 40 occurs at the moment the compressor motor is turned off when the 2-way switch 50 shifts from position A to position B and the closing coil 47 of the valve 40 is connected in parallel with the main winding 53 of the motor. At this time, the motor is still in the decelerating state. During this deceleration period, the motor operates as a generator to temporarily circulate through the closed coil 47 the current generated by the main winding 53 that moves the slide 41 to the closed position by magnetic attraction. An alternative form of electrical circuitry required to operate the blocking valve 40 is shown in FIG. In this circuit, the closed coil 47 is connected in series with a PTC-type temporary device 56 using a semiconductor element having a positive temperature characteristic.

The opening of the blocking valve 40 occurs in the same manner as described above with reference to the circuit of FIG.

Closure of the blocking valve 40 in the alternative circuit configuration causes the two-way switch 57 to switch from position A to B,
Occurs when power supply 54 is connected to a closed circuit after the motor has been disconnected.

When connected to the power supply 54, the closing coil 47 is energized to move the slide 41 to the closed position. In this case, a temporary device 56 included in the PTC element ensures that the current circulation through the closed coil 47 is temporary and after a certain time limits the current intensity to a value lower than the initial value. This temporary device 56
The deformation is shown in FIG. This circuit uses a capacitor 61
And a diode 60 connected in series with the discharge resistor 62, and the capacitor 61 and the discharge resistor 62 are connected in parallel.

After the complete stoppage of the motor according to the arrangement of FIG. 4 or the deactivation of the closed coil 47 after a period set by the temporary device 56 according to the arrangement of FIG.
41 maintains its operating position when the valve is closed by the action of the pressure difference itself between the high and constant pressure sides of the system. The opening of the outlet 44 of the fluid from the valve chamber is
It is dimensioned to ensure that in the deenergized state of the open coil 46, a closing force on the slide that is greater than the sum of all the forces acting on the slide in the direction of pulling the slide 41 away from the closed position is applied. I have.

In addition, the opening and closing electromagnetic forces acting on the slide are large enough to ensure the safe movement of the slide to its respective operating position, and the periods during which these forces are activated are "active compressor" and "stopped". It is to be understood that the pressure conditions in the system are each of a length that is unique to the two pressure operating conditions represented by the "compressor".

[Brief description of the drawings]

1 is a schematic explanatory view of a cooling device, FIG. 2 is a longitudinal sectional view of a blocking valve, FIG. 3 is a sectional view taken along line III-III in FIG. 2, and FIGS. FIG. 6 is a view showing two electric circuits of a valve having the following. FIG. 6 is a view showing a modification. 30 ... air compressor, 31 ... condenser, 32 ... capillary, 33 ... evaporator, 40 ... blocking valve.

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Marcos Gilham Schwartz 89200 Joinbil-Essie, Conjunto Belvedere 02, Brazil, Lua General Osorio (no address) (56) References JP-A-60-60 95283 (JP, A) Fully open sho 59-151078 (JP, U) Really open sho 59-4874 (JP, U)

Claims (18)

(57) [Claims] 1. A compressor, a condenser, and an exterior of the guide chamber disposed between a release position and a sealed position located within the guide chamber and remote from an outlet opening of the guide chamber. Valve control means having an electromagnetic slide (41) movable by an element for generating an applied electromagnetic force and capable of being held in the release position and the sealing position by a force other than the electromagnetic force. Wherein said guide chamber comprises a valve chamber (42) of a blocking valve (40), which is connected to said condenser (31) via an inlet opening (43) and said outlet opening. (44)
The compressor (30) is connected to an evaporator (33) on the suction side of the compressor (30) through the electromagnetic slide (4
1) the valve chamber (42) in its sealed position
The outlet opening (44) is sealed, and the entrance opening (43)
A blocking valve which is held in the sealed position by a pressure difference acting between the outlet opening and the outlet opening. 2. The blocking valve according to claim 1, wherein the non-operation of the electromagnetic slide, that is, the holding of the valve release position, is performed by the action of its own weight. 3. The blocking valve according to claim 1, wherein the actuation of the electromagnetic slide, that is, the holding of the valve sealing position, is performed by a pressure difference between a high pressure side and a low pressure side of the system. 4. A housing defining a valve chamber,
An inner annular member and an outer annular member, a pair of end walls surrounding the two annular members and the intermediate ring,
The pair of end walls and the intermediate ring radially connect the two annular members, and an electromagnetic force generating element is provided between the two annular members on each of both sides of the intermediate ring. Item 2. The blocking valve according to Item 1. 5. The inner annular member is made of a non-magnetic material,
The blocking valve according to claim 4, wherein the outer annular member, the end wall, and the intermediate ring are made of a ferromagnetic material. 6. The blocking valve according to claim 1, wherein said housing has an end wall, and an inlet passage and an outlet passage are attached to said end wall. 7. The blocking valve according to claim 6, wherein said outlet passage is defined by a projection of a capillary inwardly of said valve chamber. 8. The blocking valve according to claim 4, wherein said electromagnetic slide comprises a sealing element at an end contact surface for contacting an outlet passage. 9. The blocking valve according to claim 1, wherein the excitation of the electromagnetic generating element comprises an electric circuit of a compressor motor. 10. A motor includes a main winding, a start auxiliary winding, and a starting device, wherein the electromagnetic force generating element includes:
A valve opening coil connected in series with the start auxiliary winding and the motor starting device so as to be excited at the same time as the start of the motor, and a valve sealing coil automatically excited at the same time as the motor is not excited. The blocking valve according to claim 9, wherein 11. A motor according to claim 1, wherein the sealing coil is automatically connected in parallel with the main coil of the motor at the moment of de-energization of the motor so as to be excited by the current generated by the electric motor during the deceleration of the rotor. The blocking valve according to 10. 12. The blocking valve according to claim 10, wherein the sealing coil is connected in series to a temporary device that de-energizes the sealing coil after a lapse of time from de-energization of the electric motor. 13. The stop valve according to claim 12, wherein said temporary device comprises a PCT type element. 14. The blocking valve of claim 12, wherein said temporary device is an electrical circuit comprising a diode connected in series with a capacitor and a discharge resistor. 15. The blocking valve according to claim 10, wherein the excitation of the sealing coil is controlled by a switch provided in the compressor motor supply circuit and automatically activated according to the operating conditions of the system. 16. The stop valve according to claim 15, wherein the operating condition of the system is a temperature condition. 17. The stop valve according to claim 4, wherein said inlet and outlet passages are in end walls of a valve chamber. 18. The method according to claim 11, wherein the excitation of the sealing coil is controlled by a switch provided in a compressor motor supply circuit and automatically activated according to an operating condition of the system. A blocking valve according to claim 1.