An improved air compressor is provided. The air compressor includes a cylinder block having a head deck that defines a piston bore for reciprocal movement of a piston therein. The head deck further includes first and second ramped surfaces that slope downward toward the peripheral edge of the piston bore. A valve plate is in direct contact with the upper surface of the head deck, the valve plate having a leaf valve. During an intake stroke of the piston, the leaf valve deflects downward into direct engagement with the first and second ramped surfaces. Because the air compressor lacks a lower gasket between the valve plate and the head deck, the cost and assembly time associated with the lower gasket are eliminated.

A fluid end assembly of a hydraulic fluid pump includes a housing having a first housing bore and a second housing bore offset axially from the first housing bore. A plate is fastened to the housing. The plate has a first plate bore axially aligned with the first housing bore and a second plate bore axially aligned with the second housing bore. A first removable valve cover closes the first housing bore and a second removable valve cover closes the second housing bore. A first retainer engages the first plate bore and abuts the first removable valve cover and a second retainer engages the second plate bore and abuts the second removable valve cover.

The invention relates to a piston compressor, comprising a cylinder, a piston mounted for linear movement along a cylinder longitudinal axis (L), and a working chamber. The working chamber is fluidically connected to a working-medium inlet chamber by means of a first valve portion and to a working-medium outlet chamber by means of a second valve portion. The working chamber is delimited by an inner lateral surface, a piston end face and a working-chamber head portion, and the working-chamber head portion is formed from a geometric arrangement of the first and second valve portions. For improved efficiency, the first and second valve portions are arranged such that the working chamber is tapered toward the working-chamber heat portion.

A fluid and power provision apparatus is provided. The apparatus includes a power provision device and a pump assembly. The pump assembly includes a motor, a transmission system, a piston assembly, and a collar assembly. The piston assembly includes a piston sleeve, a piston, and a piston arm operably coupled to the piston and the transmission system to transmit energy from the motor to articulate the piston within the piston sleeve. The collar assembly forms a collar plenum, a first flowpath, and a second flowpath. The piston sleeve extends at least in part into the collar plenum. The first flowpath extends in fluid communication from the collar plenum to a fluid supply outlet. The second flowpath extends in fluid communication from an interior of the apparatus to the first flowpath.

A gas compressor with a drive power section engaging, through a seal assembly, a dual activating compressor section. The drive power section has a hydraulic drive cylinder, an upper hydraulic drive chamber, a lower hydraulic drive chamber, and a hydraulic drive piston. The dual activating compressor section has a compressor cylinder with an upper compression chamber and a lower compression chamber separated by a compressor piston, a first piston locator sensor, and a second piston locator sensor. The drive power section receives a hydraulic drive fluid and discharges spent hydraulic drive fluid. The dual activating compressor section is configured for receiving a source vapor or gas and discharging compressed vapors while the drive power section operates. The drive power section is movable between a first orientation and a second orientation.

A linear compressor includes a shell, a frame in the shell, a cylinder defining a compression space, a piston in the cylinder, a motor assembly that drives the piston, a discharge cover unit defining a discharge space that receives refrigerant from the compression space, a discharge valve that selectively opens and closes the compression space, and a valve spring assembly that provides elastic force that causes the discharge valve to contact a front surface of the cylinder. The discharge cover unit includes a cover housing, the cover housing that couples the frame, a dividing sleeve that extends from an inside of the cover housing in a longitudinal direction of the shell and that divides the discharge space into discharge chambers, and a discharge cover that inserts into the inside of the cover housing and that contacts an end portion of the dividing sleeve.

A linear compressor includes a shell, a frame in the shell, a cylinder defining a compression space, a piston in the cylinder, a motor assembly configured to drive the piston, a discharge cover unit defining a discharge space, a discharge valve configured to selectively open and close the compression space, and a valve spring assembly configured to provide elastic force that causes the discharge valve to contact the cylinder. The discharge cover unit includes a cover housing that defines an opening configured to communicate with the discharge space, a discharge cover that inserts into the cover housing through the opening, that contacts an inner surface of the cover housing, and that covers the opening, and a fixing ring configured to be positioned at an inner surface of the discharge cover. A thermal expansion coefficient of the fixing ring is greater than that of the discharge cover.

A compressor may include a housing, a piston, and a cylinder head assembly. The housing defines a cylinder and a first valve seat defining a recess. The piston is movable within the cylinder to define a compression chamber. The cylinder head assembly is mounted on the housing and includes a valve plate, a suction valve, a discharge valve and a head cover. The valve plate may be mounted to the mounting surface and may include a suction plenum, a suction passage providing fluid communication between the suction plenum and the cylinder, and a discharge passage. The suction valve can seat on the first valve seat to allow fluid flow through the suction passage. The head cover may include a discharge chamber and an integrally formed guide post extending into the discharge chamber. The guide post may include a pocket that receives a discharge valve stem for reciprocation therein.

An alternative twin cylinder air compressor including a first and a second pumping unit, arranged in line and having respective cylinders, an electric motor interposed between the pumping units, having a respective axis of rotation, the cylinders extending transversely to the axis of rotation, pneumatic connection means designed to allow the flow of air towards and away from the cylinders.

Cylinder head cover (8) for a coolant compressor, wherein the cylinder head cover (8) is attachable to the cylinder head arrangement (21) in order to form a hollow space for receiving a coolant compressed by the piston, wherein the cylinder head arrangement (21) comprises a valve plate (9) attached to the cylinder housing and having an outlet opening (11) and an outlet valve (6,7), which closes the outlet opening (11) in cycles and consists of a valve spring (10) and a stop plate (6a,7a) for delimiting an opening movement of the valve spring (10).

In order to achieve a cost-efficient production and installation of the cylinder head cover (8) while assuring a secure support of the stop plate (6a,7a), it is provided according to the invention that the cylinder head cover (8) comprises at least two contact surfaces (12,13) for supporting stop plates (6a,7a) of different outlet valves (6,7) in order to adjust different opening positions of the valve springs (10) of the different outlet valves (6,7).