Some embodiments of the present disclosure provide a compressor and an air conditioner with the compressor. The compressor includes: a first compression part, a second compression part, an intermediate cavity and an intermediate passage. Refrigerant discharged from the first compression part enters the intermediate cavity. The intermediate passage communicates with the intermediate cavity and an inner cavity of the second compression part. A bottom port of the intermediate passage is located at a bottom of the intermediate cavity, and air supplement refrigerant and/or the refrigerant discharged from the first compression part are used to convey accumulated oil in the intermediate cavity to the inner cavity of the second compression part. When only the refrigerant is used to convey the accumulated to the inner cavity of the second compression part, at least a part of the intermediate passage is located outside of a housing assembly of the compressor.

A piston rod sealing system for a reciprocating machine (1), including a piston rod (8) having a first end (8a) connected to a piston (9), and a second end (8b) connected to a crankshaft (10), the piston rod (8) being received within a housing (7); and a sealing unit (11) provided between the piston rod (8) and the housing (7), and having a first lateral surface (12a) facing the first end (8a) and a second lateral surface (12b) facing the second end (8b). The sealing unit (11) includes a first rod seal (13) positioned in the vicinity of the first lateral surface (12a) and a second rod seal (14) positioned between the first rod seal (13) and the second lateral surface (12b), the sealing unit (11) being fixed within the housing (7). The second rod seal (14) includes a liquid injection pipe (15).

According to a hermetic electric compressor of the present invention, a discharge port 66a is placed downstream of eddying flow from the joint portion 66b, a bent portion 66c is formed between the joint portion 66b and the discharge port 66a, an imaginary plumb line 66aY of an opening surface formed on the discharge port 66a is oriented to a circumferential direction of a hermetic container 10, and fluid having a small lubrication oil content is taken out from the discharge port 66a utilizing eddying flow of mixture fluid of refrigerant and lubrication oil in a gap space between a compressing mechanism 20 and a motor section 30, thereby reducing a discharge amount from the hermetic container 10.

According to a hermetic electric compressor of the present invention, a discharge port 66a is placed downstream of eddying flow from the joint portion 66b, a bent portion 66c is formed between the joint portion 66b and the discharge port 66a, an imaginary plumb line 66aY of an opening surface formed on the discharge port 66a is oriented to a circumferential direction of a hermetic container 10, and fluid having a small lubrication oil content is taken out from the discharge port 66a utilizing eddying flow of mixture fluid of refrigerant and lubrication oil in a gap space between a compressing mechanism 20 and a motor section 30, thereby reducing a discharge amount from the hermetic container 10.

A sealing system for sealing an annulus. The annulus is defined by a cylindrical interior and a cylindrical exterior within, and axially movable relative to, the cylindrical interior. The sealing system includes an inner seal (to surround and sealingly engage the cylindrical exterior), a seal support (to surround, and axially support, the inner seal), an outer seal (to surround the seal support and sealingly engage the seal support and the cylindrical interior), a first support ring (to sit behind an outer periphery of the outer seal), and a back stop (to surround the cylindrical exterior and axially support the seal support and the first ring).

A compressor includes a motor, a balance weight and a partition. The motor includes a rotor having a first end surface and a second end surface. The balance weight is disposed on the first end surface or the second end surface. The partition is disposed on the first end surface or the second end surface. The rotor has a through hole extending from the first end surface to the second end surface. The partition divides, from the through hole, at least one of a front region and a rear region. The front region is located in front of a front edge of the balance weight in a rotational direction of the rotor. The rear region is located behind a rear edge of the balance weight in the rotational direction of the rotor.

Disclosed herein is a system that performs the separation of incoming liquid and vapor oil by a single system. The disclosure is a compressed air system for separating liquid- and vapor-form oil from the air, including a filter element that comprises an air-oil separator that separates liquid-form oil from the air, an activated carbon filter positioned after the air-oil separator, separating the vapor oil from the air; and a housing, in which the said filter element is placed, having at least two discharge elements for discharging liquid-form oil, an inlet port for the inlet of air and an outlet port for the outlet of the air.

The present invention relates to a membrane-based piston pump (400) for pumping a liquid product. The pump is provided with a device (426) for maintaining a pre-defined hydraulic fluid volume in the pump. The device comprises an axle element (440) and a bushing element (432). The invention further relates to a method for pumping a liquid product in a pump. Furthermore, the invention relates to a homogenizer provided with a membrane-based piston pump.

The invention relates to a piston type expander (4) comprising: an intake cylinder head for a working fluid in the gaseous state under pressure comprising an intake opening (40) for said working fluid, an expansion zone connected to the intake cylinder head and comprising a plurality of cylinders, wherein a piston sliding in each respective cylinder is connected to a shaft (42) by a mechanical connection, each cylinder comprising at least one exhaust port (12) through which the expanded working fluid in the gaseous state can be discharged from the expansion zone, a crankcase (17) designed to contain a lubricant in the liquid state, wherein is positioned said mechanical connection, a cavity provided in the expander (4), connected to said exhaust ports, leading to an exhaust opening (41) of the expander for the expanded working fluid in the gaseous state, said cavity being designed to guide a flow of the expanded working fluid bearing a fraction of lubricant in the liquid state, said cavity (43) having a common wall with the crankcase (17) and being designed to favor the separation of the liquid lubricant fraction from the expanded working fluid in the gaseous state.

The invention relates to a piston type expander (4) comprising: an intake cylinder head for a working fluid in the gaseous state under pressure comprising an intake opening (40) for said working fluid, an expansion zone connected to the intake cylinder head and comprising a plurality of cylinders, wherein a piston sliding in each respective cylinder is connected to a shaft (42) by a mechanical connection, each cylinder comprising at least one exhaust port (12) through which the expanded working fluid in the gaseous state can be discharged from the expansion zone, a crankcase (17) designed to contain a lubricant in the liquid state, wherein is positioned said mechanical connection, a cavity provided in the expander (4), connected to said exhaust ports, leading to an exhaust opening (41) of the expander for the expanded working fluid in the gaseous state, said cavity being designed to guide a flow of the expanded working fluid bearing a fraction of lubricant in the liquid state, said cavity (43) having a common wall with the crankcase (17) and being designed to favor the separation of the liquid lubricant fraction from the expanded working fluid in the gaseous state.