RECIPROCATING-TYPE COMPRESSOR FOR REFRIGERATION AND/OR CONDITIONING AND/OR HEAT PUMP SYSTEM

Abstract

Reciprocating-type compressor for refrigeration and/or conditioning and/or heat pump systems, comprising—a casing in which there is defined at least one compression section comprising at least one cylinder and a corresponding compression piston, —a head provided on said casing, defining a delivery chamber immediately down-stream of said compression section, and adapted to receive the compressed fluid from said compression section, —an intake zone from where the fluid to be compressed in the at least one cylinder of said compression section is introduced, —a delivery tap at the operational outlet of said compression chamber, characterized in that it comprises a check valve placed between said operational outlet of said compression chamber and said delivery tap, adapted to prevent the return of fluid into the compression chamber from said delivery tap.

Claims

1) Reciprocating-type compressor structure for refrigeration and/or conditioning and/or heat pump systems, the compressor structure comprising a casing in which there is defined at least one compression section comprising at least one cylinder and a corresponding compression piston, a head provided on said casing, defining a delivery chamber immediately downstream of said compression section, and adapted to receive the compressed fluid from said compression section, an intake zone from where the fluid to be compressed in the at least one cylinder of said compression section is introduced, a delivery tap at an operational outlet of said compression chamber, and a check valve, placed between said operational outlet of said compression chamber and said delivery tap, adapted to prevent the return of fluid into the compression chamber from said delivery tap.

2) Compressor structure according to claim 1, wherein said check valve is a swing check valve.

3) Compressor structure according to claim 2, wherein said swing check valve is a gravity-closing type swing check valve.

4) Compressor structure according to claim 2, wherein said swing check valve comprises a closing flap hinged at the side to the passage to be closed; said flap lifting with the passage of a flow from said compression chamber towards said delivery tap and closing against the passage due to gravity when the flow stops.

5) Compressor structure according to claim 1, wherein said check valve is housed in a compartment comprising a floor wherein there is the passage to be closed towards the compression chamber, and a ceiling against which said flap moves to the open position, with a position inclined with respect to the axis of opening, with the closing face of the flap turned towards the passage to be closed; said inclined position is between 15° and 75°.

6) Compressor structure according to claim 5, wherein said compartment is defined at least in part on said head; the floor of said compartment and at least part of the walls of the compartment are defined in said head.

7) Compressor structure according to claim 6, wherein said delivery tap is fixed to said head in a water-tight manner, by means of threaded elements, said ceiling being defined in the body of said tap.

8) Compressor structure according to claim 4, wherein said check valve comprises a collar wherein there is defined a hole for the passage of fluid, to which said closing flap is hinged, there being present in said head a housing recess for said collar; said collar having at least one threaded element for fixing to said head.

9) Compressor structure according to claim 1, wherein said head is fixed in a water-tight manner, by means of threaded elements, to said casing.

10) Compressor structure according to claim 1, wherein each compression section comprises an intake and delivery valve-holder body placed between the relative head and said casing.

11) Compressor structure according to claim 1, comprising several compression sections, angularly offset from one another around the control axis of rotation of the crank gear driving the compressor pistons, each section comprising one or more compression cylinders and relative pistons.

12) Compressor structure according to claim 11, wherein said head comprises a common delivery chamber for all the compression sections, into which the fluid compressed by the cylinders of the compression sections is sent.

13) Compressor structure according to claim 11, wherein said head comprises one or more intake chambers for the compression sections, from which the fluid is introduced into the cylinders of the compression sections.

14) Compressor assembly comprising a compressor structure according to claim 1, wherein said compressors have their respective delivery taps connected to one another in parallel, wherein said compressors are connected to a common delivery conduit, and have the same delivery pressure, and wherein one or more of said compressors may be non-operational while the others are operational.

15) Refrigeration and/or conditioning and/or heat pump system, comprising a plurality of compressors with a compressor structure according to claim 1, arranged in parallel, wherein the plurality of compressors are connected to a common delivery conduit, and so said compressors have at least their respective delivery taps connected to one another in parallel.

16) Method of installation of a refrigeration and/or conditioning and/or heat pump system, the method comprising the step of: providing a plurality of compressors comprising a compressor structure for refrigeration and/or conditioning and/or heat pump systems, the compressor structure comprising: a casing in which there is defined at least one compression section comprising at least one cylinder and a corresponding compression piston; a head provided on said casing, defining a delivery chamber immediately downstream of said compression section, and adapted to receive the compressed fluid from said compression section; an intake zone from where the fluid to be compressed in the at least one cylinder of said compression section is introduced; a delivery tap at an operational outlet of said compression chamber; and a check valve, placed between said operational outlet of said compression chamber and said delivery tap, adapted to prevent the return of fluid into the compression chamber from said delivery tap; and connecting in parallel to one another, to a system branch, the plurality of the compressors, wherein said compressors have their respective delivery taps connected to one another in parallel, wherein said compressors are connected to a common delivery conduit, wherein said compressors have the same delivery pressure, and at least some of said compressors have a common intake branch.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] Further characteristics and advantages of the invention will become more apparent from the following description of a preferred but non-exclusive embodiment thereof, illustrated by way of non-limiting example in the accompanying drawings, wherein:

[0034] FIG. 1 shows a cross section, at least partly along the line II-II shown in FIG. 2, of an upper portion and end portion of a compressor with a structure according to the invention;

[0035] FIG. 2 shows a cross section, at least partly along the line I-I shown in FIG. 1, of the upper portion of the compressor shown in FIG. 1;

[0036] FIG. 3 shows an enlargement of FIG. 1, showing the area of the check valve at the outlet from the compressor delivery chamber, wherein the valve is closed;

[0037] FIG. 4 shows an axonometric view of a check valve used in the compressor shown in the previous figures;

[0038] FIG. 5 shows a generic layout of a conditioning system, using a plurality of compressors as shown in the previous figures, mounted in parallel; each compressor is connected to a delivery conduit, external to the compressor structure, in other words not part of the compressor.

DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION

[0039] With reference to the aforesaid figures, a compressor with a structure according to the present invention is indicated as a whole with the number 10. A conditioning system (for example for heating the domestic water supply, heating or cooling the environment) using a plurality of compressors 10 arranged in parallel is indicated as a whole with the number 100. In FIG. 5, the system shows the compressors 10 in parallel, to which are associated outlet conduits that connect in a common delivery conduit 101, and a common intake conduit 102. Compressor outlet conduits, delivery and intake conduits are external to the compressor structures, in other words they are part of the system but not of the compressors. The system, as is well known, schematically consists of an oil separator 103, a condensing unit 104 for heat exchange with the utilities 105, an expander 106 and an evaporator 107.

[0040] Each compressor 10 is, for example, a multi-cylinder compressor and comprises a casing 11 in which there is housed a motor, for example an electric motor (not shown in the figures) to which is associated an output shaft on which are mounted the connecting rods 12 (only one of which is visible in the figures) carrying at the end pistons 13 (only one of which is visible in the figures) arranged in corresponding cylindrical sleeves 14 (or cylinders, for short) created on the periphery of the casing 11 (i.e. on the upper part, with reference to the figures). Connecting rods, pistons, cylinders and valves make up the intake/compression members. Each combination of connecting rod, cylinder and piston defines a compression section of the compressor. Lubricant oil is contained inside the casing 11 in which the shaft and connecting rods 12 turn.

[0041] In this example, the casing 11 has three casing portions 11A, angularly offset from one another by 60° with respect to the axis of the compressor motor, and on each of which there are defined one or more compression sections (in the figures only one compression section, the central one, is fully visible)

[0042] Each compression section also comprises intake and delivery valves. In particular, the cylinders 14 are open on respective upper surfaces 15, on which are placed intake and delivery valve-holder plates 16, which close the cylinders. On each plate 16 there are holes, appropriately closed by the delivery and intake valves, of a known type. The figures show only the passages relating to the delivery valves, with which the delivery valves, which are small and not very visible, are associated. Delivery passages and relative delivery valves are indicated by the number 20. The number 16A is used to indicate the limit stops.

[0043] Positioned on the plates 16 is the compressor head 17, defining a single delivery chamber 18, into which the refrigeration fluid compressed in the cylinder is sent, and intake chambers 19 from which the refrigeration fluid is taken into the cylinder 14.

[0044] In particular, in this example, there is a single head 17 connected in a water-tight manner, by means of threaded elements, to the plates 16 and to the portions 11A of the casing 11, and which defines a single delivery chamber 18, on which all the compressor cylinders open (by means of the relative delivery valves 16A), and the intake chambers 19, on which the respective cylinders open by means of the relative intake valves.

[0045] On the head 17 there is a delivery tap 22, which allows connection of the compressor 10 to the delivery conduit 101 common to all the other compressors 10 in the system 100. The delivery tap is fixed to the head 17, in a water-tight manner, by means of threaded elements. In practice, the conduit connected to the delivery tap is external to the compressor, in other words it is not part of it.

[0046] In particular, at the delivery tap 22, the head 17 comprises an operational outlet in the form of a passage 23 connecting the delivery chamber 18 to a compartment 24 in which there is a check valve 25, adapted to prevent fluid returning to the compression chamber from the tap in the event that the compressor is not in operation and one or more of the other compressors 10 is in operation. The tap 22 enables controlled communication between the compartment 24 and the delivery conduit 101.

[0047] It is clear that the check valve is inside the compressor structure.

[0048] In particular, the check valve 25 is a swing check valve and comprises a closing flap 26 hinged at the side to the passage 23. The flap 26 lifts with the passage of a flow from the delivery chamber 18 towards the delivery tap 22 and re-closes against the passage 23 due to gravity when the flow stops. The lower face of the flap 26, which is preferably made of metallic material, is characterized by a surface finish with very low degree of roughness, in practice a surface with a polished mirror surface, and has a high degree of hardness. The horizontal surface on which the flap rests when it is closed is also preferably made of metallic material, and has a similar surface finish with low degree of roughness and a high degree of hardness, thereby guaranteeing an excellent seal.

[0049] In the example described, the check valve 25 comprises a collar 27 in which there is a hole defining the passage 23 for the fluid.

[0050] The closing flap 26 is hinged to this collar 27. On the head 17 there is a housing recess 28 for the collar 27, which is fixed to the head by threaded elements 29.

[0051] The compartment 24 in which the closing flap 26 is housed comprises a floor 24A defined by the upper surface of the collar 27, walls 24B defined mainly by the housing recess 28 on the head 17, and a ceiling 24C created by the body of the delivery tap. On the ceiling 24C there is a hole 24D connecting the compartment 24 with the outlet of the tap 22 towards the conduit 101.

[0052] The ceiling 24C is shaped so as to form a rotational limit stop 24E for the flap 26 when in the lifted, or open, position. In practice, when the flap is at the maximum open position, it meets the limit stop 24E thereby defining its inclined position with respect to the X-axis of the hole 23 (with the closing face of the flap turned towards the hole 23). Preferably, this inclined position is between 15° and 75° with respect to the X-axis. Furthermore, in the inclined raised position, the flap partially obstructs the hole 24D.

[0053] In practice, according to the description, in the compressor according to the invention, a swing check valve has been installed at the outlet of the delivery chamber in order to reduce drastically recirculation between intake and delivery.

[0054] The valve is characterized by a flap which is lifted by the flow of compressed refrigerating fluid.

[0055] The lower face of the flap is characterized by a mirror-finish surface and a high degree of hardness. The horizontal surface on which the flap rests also has an excellent surface finish and a high degree of hardness. The tap is shaped on the inside to accommodate the movement of the flap and to halt its lifting in an oblique position so as to limit turbulence and drops in pressure.

[0056] The absence of elastic elements in the check valve makes the device very stable.

[0057] In the event that the compressor stops, gravity causes the flap to close until it comes into contact with the sealing face.

[0058] The surface characteristics of the contact faces of the flap/delivery chamber passage, combined with the high pressure upstream and downstream of the valve, considerably limits the amount of recirculation with a consequent positive impact on system efficiency.

[0059] It is understood that the drawings only show possible non-limiting embodiments of the invention, which can vary in forms and arrangements without however departing from the scope of the concept on which the invention is based. Any reference numerals in the appended claims are provided purely to facilitate the reading thereof, in the light of the above description and accompanying drawings, and do not in any way limit the scope of protection.