RU2471105C1 - Expansion valve containing mixing device - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: expansion valve includes inlet hole, at least two outlet holes, each of which is intended for discharge of fluid medium contained at least partially in gaseous state. The first valve component includes at least two valve seats. The second valve component includes at least two gate elements. The latter are moved simultaneously towards valve seats and from them. Displacement device is intended for displacement of gate elements and valve seats. The second valve component and gate elements are connected so that mutual position of the first valve component and the second valve component determines the opening degree of each of the valves. The above opening degree is controlled synchronously, which allows maintaining the required distribution of the flow in outlet holes. Valve components include a part made in the form of disc and containing the above valve seats or gate elements on its surfaces. Valve seats have the shape of through holes in the disc forming the first valve component. Gate elements have the shape of projecting elements on the surface of the disc forming the second valve component located opposite the first valve component. Cooling system is described as well.

EFFECT: possibility of controlling the fluid distribution in two or more parallel flows is provided.

2 cl, 2 dwg

Description

Technical field

The present invention relates to an expansion valve, in particular, used in cooling systems, for example in air conditioning systems. The expansion valve according to the present invention is intended to separate the fluid into at least two parallel flows, for example, by directing it into at least two parallel mounted evaporators or two parallel mounted evaporator tubes.

State of the art

In a circulation circuit such as a refrigerant circuit of a cooling system, it is sometimes necessary to divide a stream into two or more parallel flows in a part of the circuit. The need for this arises, for example, in cooling systems containing two or more evaporators installed in parallel. In addition, it may be necessary to control the flow rate of the medium directed through each of the parallel flows, for example, to ensure essentially equal distribution of the medium or optimal operation of the system in terms of energy consumption or efficiency.

In some previous attempts to control the distribution of refrigerant over two or more parallel flows in a cooling system, a distributor was installed in the refrigerant path behind an expansion valve. Thus, the separation of the refrigerant flow occurred after its expansion, i.e. when the refrigerant was predominantly in a gaseous state. The disadvantage of this design is the difficulty of controlling the flow of refrigerant to obtain essentially equal distribution in parallel flows.

SUMMARY OF THE INVENTION

In embodiments of the present invention, the aim is to propose an expansion valve that allows you to control the distribution of fluid in two or more parallel flows.

Another objective of the embodiments of the claimed invention is to provide an expansion valve that provides easy control of the distribution of the liquid in two or more parallel flows.

In its first aspect, the present invention provides an expansion valve comprising

- the inlet into which fluid enters in a liquid state,

- at least two outlet openings, through each of which a fluid can be released, which is at least partially in a gaseous state,

- a first component of the valve having at least two valve seats, each of which is connected with the possibility of passage of fluid with one of the outlet openings,

- the second component of the valve having at least two gate elements, and each gate element is made in such a way that the valve seats and gate elements in pairs form at least two valves,

- while the first component of the valve and the second component of the valve are made with the possibility of essentially such a linear movement relative to each other, in which the shutter elements simultaneously move towards the valve seats and away from them,

- bias device designed to bias the shutter elements and valve seats in a position that determines the minimum degree of opening of the valves, or in a position that determines the maximum degree of opening of the valves,

in which the second valve component and the shutter elements are connected in such a way that the relative position of the first valve component and the second valve component determines the degree of opening of each of the valves, and the specified degree of opening is controlled synchronously, which allows you to maintain the necessary flow distribution over the outlet openings,

wherein the valve components comprise a part having a substantially disk shape and having valve seats or closure elements on their surfaces, respectively, the valve seats being in the form of through holes in the disk forming the first valve component, and the closure elements are in the form of protruding elements on the surface of the disk forming the second valve component located opposite the first valve component.

An expansion valve according to the claimed invention determines the flow of fluid between the inlet and at least two outlet openings. The fluid enters the inlet in a liquid state and exits the outlet openings, at least in part, in a gaseous state. In the context of the present invention, the term "liquid state" means that the fluid entering the expansion valve through the inlet is essentially in the liquid phase. As used herein, the phrase “at least partially in a gaseous state” means that the fluid leaving the expansion valve through the outlet openings is completely in the gas phase or at least part, for example, a significant part of the volume of fluid the medium leaving the expansion valve is in the gas phase. Accordingly, at least a portion of the fluid entering the expansion valve undergoes a phase transition from the liquid phase to the gas phase as it passes through this valve.

The inlet and outlet are preferably fluidly coupled to one or more other components, such as components of a cooling system. The expansion valve is preferably part of a fluid system, such as a circulation loop.

The expansion valve comprises a first valve component and a second component configured to move relative to each other. This can be achieved by installing the first and / or second component of the valve so that it (they) can move relative to the rest of the expansion valve. So, the first valve component can be mounted movably, and the second valve component can be fixed. Alternatively, the second valve component may be mounted movably, and the first valve component may be stationary. Finally, both components of the valve can be mounted movably. In all the situations described above, relative movement between the first valve component and the second valve component is possible, which determines the relative position of the first and second valve components.

The first valve component comprises at least two valve seats, each of which is fluidly connected to one of the outlet openings. At least two gate elements are designed in such a way that the valve seats and the gate elements form at least two valves in pairs. The shutter members are also connected to the second valve component so that the relative position of the first valve component and the second valve component determines the degree of opening of the valves. Thus, the shutter members preferably move relative to the valve seats when the first valve component and the second valve component move relative to each other. The degree of opening of the valves and thereby the amount of fluid entering each of the outlet openings can be controlled by adjusting the relative position of the first and second components of the valve. Since the degree of opening of the valves is determined by the relative position of the first and second components of the valve, it is adjusted for passages synchronously, which allows you to maintain at least essentially the necessary flow distribution over the outlet openings.

The expansion valve further comprises a biasing device designed to bias the shutter members and valve seats to a position that defines the minimum degree of opening of the valves, or to a position that determines the maximum degree of opening of the valves. When the biasing device moves the shutter elements and valve seats to a position that determines the minimum degree of opening of the valves, it tends to close the valves, therefore, to use the expansion valve with open valves, it is necessary to overcome this biasing force created by the biasing device. On the contrary, when the biasing device moves the shutter elements and valve seats to a position that determines the maximum degree of valve opening, it seeks to keep the valves open, therefore, to use the expansion valve with the valves closed, it is necessary to overcome this biasing force created by the biasing device.

In any case, the bias force created by the biasing device determines the equilibrium point for the relative displacements of the valve seats and gate elements. Thus, with proper execution and positioning of the biasing device, it is possible to achieve a correspondence between the applied biasing force, providing relative movement of the valve parts, and the required degree of opening of the valves. For example, the biasing force can be selected in such a way as to ensure a smooth closing of the valve, and / or so that when a certain biasing force is applied, a certain degree of opening is provided.

The shutter elements are part of the second component of the valve. In this embodiment, a direct consequence of the relative movements of the first and second components of the valve are the corresponding relative movements of the valve seats and valve elements. The relative movement of the first and second components of the valve is essentially linear movement, as a result of which all the shutter elements will simultaneously move towards and away from the respective valve seats. Valve components comprise a part having a substantially disk shape and containing valve seats or closure elements, respectively, on their surfaces. The valve seats are in the form of through holes in the disk forming the first valve component, and the gate elements are in the form of protruding elements on the surface of the disk forming the second valve component, located opposite the first valve component.

Alternatively, the shutter elements may be separate parts that are functionally associated with the second component of the valve. According to this embodiment, the shutter elements and the second valve component can be located on opposite sides of the first valve component so that moving the first and second valve components towards each other can cause the second valve component to simultaneously press the shutter elements away from the valve seats, increasing thereby, the degree of opening of the valves, determined by the gate elements and valve seats. In this case, the biasing device will preferably push the shutter members in the direction of the valve seats. Whereas when the first and second components of the valve are removed from each other, the biasing device will ensure the closure of the gate elements to the valve seats with a decrease in the degree of opening of the valves.

The biasing device may be or comprise at least one spring, for example a compression spring. The spring may be in a compressed state, in which case the spring will push apart two parts, for example, the first and second valve components or the first valve component and one or more gate elements. Alternatively, the spring can be in a stretched state, and then the force of the spring will shift two parts, for example, the first and second components of the valve or the first component of the valve and one or more gate elements to each other.

The shutter elements may be needle or ball. In addition, the gate elements may be of any other suitable type.

The expansion valve may further comprise a thermostatic element, wherein the first valve component and / or the second valve component can be operatively connected to the thermostatic element, while this thermostatic element will determine the relative movement of the first valve component and the second valve component. In such an embodiment, the thermostatic element determines the degree of opening of each valve due to valve seats and gate elements, i.e. the thermostatic element determines the mass flow at the same time for all flows directed through the outlet openings.

In this case, the biasing device can counteract the movements caused by the thermostatic element in response to an increase in pressure. In this embodiment, the biasing force generated by the biasing device and the displacement force initiated by the thermostatic element in response to a pressure change create an equilibrium by their interaction that determines the degree of opening of the valves.

Alternatively, the relative movements between the components of the valve and thereby the degree of opening of the valves, determined by the valve seats and gate elements, can be controlled by other suitable actuating mechanisms.

According to a second aspect of the claimed invention, there is provided a cooling system comprising

at least one compressor,

at least one capacitor

at least two evaporators installed in parallel in the refrigerant path of the cooling system, and

- an expansion valve according to the above disclosed, which is designed so that each of its valves is configured to supply refrigerant to one of the evaporators.

Thus, the expansion valve according to the first aspect of the claimed invention, preferably, can be installed in the path of the cooling system, for example the cooling system used in the refrigeration unit, or in the air conditioning system.

Brief Description of the Drawings

The invention will now be described in more detail with reference to the accompanying drawings, in which:

figure 1 shows a section of the expansion valve according to the first implementation of the invention, and

figure 2 shows a section of the expansion valve according to the second implementation of the invention.

Claims (8)

1. An expansion valve (1) comprising:
an inlet intended for fluid inlet in a liquid state,
at least two outlet openings (8), each of which is designed to discharge a fluid that is at least partially in a gaseous state,
the first component (2) of the valve, comprising at least two valve seats (3) made therein, each of which is fluidly connected to one of the outlet openings (8),
a second valve component (4) having at least two shutter elements (5), each shutter element being configured such that the valve seats (3) and the shutter elements (5) form at least two valves in pairs, the first component (2) the valve and the second component (4) of the valve are made with the possibility of essentially such a linear movement relative to each other, in which the shutter elements (5) simultaneously move towards and away from the valve seats (3),
a biasing device designed to bias the shutter elements (5) and valve seats (3) to a position that determines the minimum degree of opening of the valves, or to a position that determines the maximum degree of opening of the valves,
in which the second component of the valve (4) and the shutter elements (5) are connected in such a way that the relative position of the first component (2) of the valve and the second component (4) of the valve determines the degree of opening of each of the valves, and the specified degree of opening is controlled synchronously, which allows maintain the necessary flow distribution over the outlet openings (8),
wherein the valve components comprise a part having a substantially disk shape and having said valve seats or closure elements respectively on their surfaces, the valve seats being in the form of through holes in the disk forming the first valve component, and the closure elements are in the form of protruding elements on the surface of the disk forming the second component of the valve, located opposite the first component of the valve. 2. The expansion valve (1) according to claim 1, in which the shutter elements (5) are separate parts that are functionally associated with the second component (4) of the valve. 3. The expansion valve (1) according to claim 1 or 2, in which the biasing device is or comprises at least one spring. 4. The expansion valve (1) according to claim 1 or 2, in which the shutter elements (5) are needle-type elements. 5. The expansion valve (1) according to claim 1 or 2, in which the shutter elements (5) are ball type elements. 6. An expansion valve (1) according to claim 1 or 2, further comprising a thermostatic element, in which the first component (2) of the valve and / or the second component (4) of the valve are operatively connected / connected to the thermostatic element, wherein the relative movements of the first component (2) the valve and the second component (4) of the valve are due to this thermostatic element. 7. The expansion valve (1) according to claim 6, in which the biasing device is configured to resist movements caused by a thermostatic element in response to an increase in pressure. 8. The cooling system, including:
at least one compressor
at least one capacitor
at least two evaporators installed in parallel in the refrigerant path of the cooling system, and
expansion valve (1) according to any one of claims 1 to 7, made in such a way that each of its valves is configured to supply refrigerant to one of the evaporators.

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