NO122928B - - Google Patents

Description

Pressure control valve for refrigeration compressors.

The present invention relates to a pressure control valve for regulating the control pressure on a multi-cylinder refrigeration compressor's slide control valve to relieve a number of cylinders corresponding to the immediate cooling demand, which pressure control valve has a nozzle standing in connection with the control pressure on the slide control valve, which can be opened and closed using a bellows , if internal pressure dependent on the compressor's suction pressure can be counteracted with an adjustable spring to determine the desired.. cold range.

When the compressor's suction pressure changes, the bellows will contract or expand, and these movements are transferred by previously known control valves to the nozzle closing mechanism using

of rods, which are displaced in guide holes, or rotatable rocker arms,

and the friction arising in the steering and turning stages causes hysteresis, so that exact regulation becomes impossible. In addition, the known pressure control valves have the disadvantage that the desired difference range can only be changed by replacing springs or changing the pivot point of the rocker arms, and apart from the difficulties with this, in the latter case it only enables a variation in steps .

The purpose of the invention is to indicate how, with a pressure control valve of the type in question, a hysteresis-free control pressure regulation can be achieved as well as a continuous variation of the tolerance in the set cold range, usually and hereinafter called the "differ-ansen", and for that purpose the pressure control valve -according to the invention characterized by the fact that a disc-shaped nozzle closing plate is mounted in such a way in relation to the bellows that, under axial action as a result of a - contraction of the bellows, it will position itself obliquely in relation to the nozzle, as well as by the fact that the place where the nozzle closing plate must cooperate with the nozzle can be changed by -rotation of the nozzle closing plate and the nozzle in relation to each other. The nozzle closing plate will oscillate around the incline depending on the variation of the suction pressure.

Contraction of the bellows will, at a certain suction pressure, cause a certain inclined position of the nozzle closing plate. For the same inclined position of the nozzle closing plate, the distance from this number of nozzles will then be determined by the mutual rotation.

According to the invention, the pressure control valve can advantageously be designed in such a way that the nozzle closing plate with its center is axially and rotatably fixedly connected to the bellows, and that it is further connected to the bellows at places located at an axial distance from each other by a rotatable but not axially displaceable with the bellows part using leaf springs. In case of axial displacement as a result of a contraction of the bellows, the leaf springs will pull to each side, so that the nozzle closing plate is tilted to an inclined position, and at a given inclined position the distance from the nozzle to the opposite point of the nozzle closing plate in the open position will be predetermined by the nozzle closing plate's rotation relative to the nozzle.

In another embodiment, the pressure control valve according to the invention can be arranged such that the nozzle closing plate is resilient and with its center axially and. rotationally firmly connected to the bellows, and that a single place on the edge of the nozzle closing plate is attached to a part which can be turned with the bellows. As the nozzle does not change position, when the nozzle closing plate is turned, the point of the nozzle closing plate opposite the nozzle in the open state will have a greater or lesser distance from the nozzle.

In the aforementioned embodiments, the nozzle closing plate is rotatable with the bellows. According to the invention, however, the pressure control valve can also be designed in such a way that the nozzle closing plate is spring-loaded and fixed at a location at some distance from the connection point with the bellows, and that the nozzle's distance from the closing plate's fixing point is adjustable, preferably by the nozzle being placed on a relative to the nozzle closing arm rotatable arm. For a given inclined position of the nozzle closing plate, the nozzle's release will then be larger or smaller corresponding to the distance from the attachment point.

The pressure on the slide control valve, the control pressure, without the use of a pressure control valve, will be mainly constant and equal to or proportional to the compressor's oil pressure. With the use of a pressure control valve, the control pressure acts at the same time in the nozzle of the pressure control valve, and its nozzle will be closed, as long as the cooling demand and thus the compressor's suction pressure is so strong that it corresponds to the compressor's full capacity. If the compressor's suction pressure now falls, which also acts on the side of the nozzle closing plate opposite the nozzle, the pressure control valve's bellows will cause the nozzle closing plate to open for the nozzle, so that the control pressure falls. Thereby, the slide control valve will disconnect one or more compressor cylinders, until the suction pressure finds an operating equilibrium with a suitable number of compressor cylinders.

The spring acting on the bellows of the pressure control valve for setting the desired cold range is adjusted according to the internal pressure in the bellows and the pressure around the bellows. With the pressure control valve in question, you now have the option of continuous variation by changing the pressure difference on the bellows, e.g. by changing the pressure surrounding the bellows, which is usually atmospheric pressure, by replacing this with a varying pilot pressure. This has

previously made use of by putting the space around the pressure control valve's bellows in connection with an air line, in which the pressure can be regulated, e.g. if a certain number of compressors are connected to the same plant, which for a period of the day must work at a different cold area -.

When using the pressure control valve, you proceed

in such a way that a variable is added to the space around the bellows

pilot pressure, which is regulated using a pressure regulator depending on the compressor's suction pressure. In this way, an adaptation of the compressor to fluctuating cooling requirements is achieved automatically. By e.g. falling suction pressure in the compressor, the pilot pressure around the pressure control valve's bellows will rise, compressing the bellows more, so that the nozzle closing plate releases the nozzle, and thereby the control pressure on the slide control valve drops so that it disconnects one or more compressor cylinders.

Compressed air is used to provide the pilot pressure, which is also supplied to the nozzle in a pressure regulator of the same design as the pressure control valve, but where the opposite side of the nozzle closing plate, where the nozzle is lying, is connected to the free air, while the space around the pressure regulator's bellows is connected to the suction side of the compressor. This achieves the same hysteresis-free stepless pressure variation as with the pressure control valve itself. By e.g. falling suction pressure, the pressure regulator's bellows will expand and pull the nozzle closing plate towards the nozzle to close it, and thereby the pilot pressure of the pressure control valve rises, so that its nozzle opens, whereby the control pressure on the slide control valve falls and causes the slide control valve to disengage one or more compressor cylinders.

You can also proceed on. the way that refrigerant gas is used to provide the pilot pressure, which is also supplied to the nozzle in a pressure regulator of similar construction to the pressure control valve, but with the nozzle lying on the same side of the nozzle closing plate as the connection to the suction side of the compressor and with the space around the pressure regulator's bellows standing in connection with-the free.

In the case of falling suction pressure, the pressure regulator's nozzle closing plate will close the nozzle, which will cause a rising pilot pressure to the pressure control valve, which will therefore open its nozzle, whereby the control pressure falls and the slide control valve will disconnect one or more compressor cylinders. The refrigerant gas flowing out through the nozzle is led away through the suction pressure connection.

A further possibility is that refrigerant gas is used to provide the pilot pressure, which is controlled by a thermostatic pressure regulator, which is connected to a sensor placed in the medium whose temperature is to control the plant's capacity.

The invention shall be explained in more detail below with reference to the drawing,, on which

fig. 1 shows a section through an embodiment of a

pressure control valve according to the invention, which valve can also be used as a pressure regulator for pilot pressure for the pressure control valve,

fig. 2 a section corresponding to the left side of that in fig. 1 showed a pressure control valve, arranged as a pressure regulator for the use of refrigerant gas as pilot pressure, and

fig. 3 an alternative embodiment for a pressure control valve according to the invention.

In fig. 1, a bellows 10 is enclosed in a bellows housing 11 and is with its ends airtightly attached partly to an end plate 12, partly to a bellows door 13 that can be moved inside the housing, which at one end passes through the end plate 12 and an end wall 14 of the bellows housing 11. The bellows door 13. is held in position by means of coil springs 15 and 16, the first of which rests against the end wall 14 and the second against an adjustable stop 173 which is guided axially at the end of the bellows housing and can be adjusted from the outside...

The bellows housing 11 can be turned in an outer housing 18 with a purpose, which will be explained later. In the outer housing there is a bore 19 for the connection of a line or channel, not shown, which is connected to the compressor's slide control valve influencing control pressure, which determines the number of connected compressor cylinders. The outer housing is closed with a cover 20, in which is a nozzle 21 standing in connection with the bore 19 and opening into the cover edge, and above the cover edge is a nozzle closing plate. 22. The nozzle closing plate is surrounded by a cap 23 that closes to the cover 20, in which there is an opening 24, which is connected to the suction side of the compressor, e.g. with the chrome pin housing.

The nozzle closing plate 22 is essentially in the shape of a disk, as with the one in fig. The embodiment shown in 1 has at its center a pin 25 attached to it and projecting towards the bellows mandrel, which is axially and rotationally firmly connected to the bellows mandrel 13 through a spindle 26 projecting into the latter, which is secured in the bellows mandrel by means of, e.g. one. pinion screw. Eccentrically in relation to the pin 25 and on mainly diametrically opposite sides of this, two projections or pins 27 are attached to the end wall 14 of the bellows housing and

28, and these are connected by means of two leaf springs 29 and 3°, respectively, to the nozzle closing plate's pin 25 at places located at an axial distance from each other.

The room in the bellows housing 11. around the bellows 10 is through an opening 31 in the bellows housing and an opening 32 in the outer housing set in front-'"

connection with a source of pilot pressure, which is primarily atmospheric pressure, when the described pressure control valve is used without a pilot pressure regulator.

When the load on the compressor decreases, the suction pressure in the chrome tap housing of the compressor will drop and through the opening 24 in the cap 23 and the openings in the nozzle closing plate, the pressure variation will propagate to the interior of the bellows. The bellows thereby contracts, so that the nozzle closing plate 22 is lifted from the nozzle 21, and through the bore 19, the control pressure on the slide control valve is thereby equalized to a greater or lesser extent corresponding to the degree of opening of the nozzle, so that the slide control valve changes the number of engaged cylinders.

The degree of opening for the nozzle 21 is for a certain setting of the desired cold range by means of the stop 17 determined by the position of the pins 27 and 28 in relation to the nozzle 21. When the pins 27 and 28 as shown in fig. 1 lies in the plane containing the nozzle

21, during axial movement to the left, the nozzle closing plate 22 will position itself obliquely by tilting about an axis, which is perpendicular to the plane of the drawing at a place diametrically opposite the nozzle, and will act from the pin 25

than the nozzle. If the plane of the pins 27 and 28 is rotated in relation to the plane of the drawing, in which the nozzle 21 and the pin 25 are located, and this can be done in the one in fig. 1 embodiment occurs by turning the bellows housing 11, for tilting of the nozzle closing plate the nozzle 21 will come to be at a place on the edge of the nozzle closing plate which has less distance from the nozzle, and thereby its degree of opening is reduced.

On the one in fig. 1 embodiment, the nozzle closing plate 22 is rotated together with the bellows housing 11 as a result of the rotationally fixed connection through the pins and the leaf springs. However, according to the invention, other embodiments are possible for providing the springy inclined position of the nozzle closing plate in relation to the nozzle. A simple embodiment can thus consist of the leaf springs being omitted and the nozzle closing plate itself being made springy, the nozzle closing plate then being connected to the bellows housing at a place on its edge, more specifically the place shown in fig. 1 is closest to pin 27-

With the pressure control valve described above, the degree of contraction of the bellows will be determined by the suction pressure inside the bellows and the prevailing atmospheric pressure around the bellows. A further regulation with the pressure control valve can now be achieved by supplying a pilot pressure instead of the atmospheric pressure, which is suitably varied, e.g. depending on the suction pressure in the compressor, i.e. corresponding to its load. This pilot pressure can conveniently be provided by a pressure regulator whose design is identical to the described pressure control valve, only the connections being different.

A first possibility is to use compressed air to provide the pilot pressure, and the opening 32 in the pressure control valve is then connected to a compressed air line, which is also connected to the bore 19 in a pressure regulator, whose opening 25 is connected to the free air, while the space around the pressure regulator's bellows 10 is connected, to the suction side of the compressor. A decreasing suction pressure will then keep the nozzle closing plate 22 closed, so that the pilot pressure in the bore 19 rises. However, the same pilot pressure acts in the connected pressure control valve's bellows housing 11, the bellows is pressed together, and the nozzle 21 is opened, and the slide control valve disconnects one or more compressor cylinders, until there is operational equilibrium again.

Another possibility is to use refrigerant gas as a source for the pilot pressure. This refrigerant gas will not be allowed to go to waste by allowing it to escape through a pressure regulator opening 24 into the open air, and by arranging a pressure control valve according to fig. 1 as a pressure regulator, a few changes must then be made.

These changes can be seen from Fig. 2, as the rest of the pressure regulator

is as in fig. 1 and with atmospheric pressure around the bellows. Fig. 2 is otherwise only different from fig. 1 by the nozzle closing plate opening in the opposite direction, as the pressure medium acting as pilot pressure is supplied to a nozzle 33 in the cap 23• When opening the nozzle 33, the pressure medium will then flow to the compressor's suction side through the opening 24-When falling suction pressure brings the nozzle closing plate 22 in the pressure regulator to close the nozzle 33, the pilot pressure will rise, and when the pilot pressure is propagated to the space around the bellows in the connected pressure control valve, this nozzle will be opened, so that the control pressure on the slide control valve falls, i.e. one or more compressor cylinders are disconnected.

In the alternative embodiment of fig. 3, the place on the nozzle closing plate 22, which cooperates with the nozzle 21, is varied by turning the nozzle instead of the nozzle closing plate. which is here attached to the cap 23 designed as a cover at 34, °S during expansion and contraction of the bellows 10, the spring 15 will cause the nozzle closing plate 22 to follow the axial movements of the bellows mandrel, so that the nozzle closing plate assumes an inclined position conditioned by this. The nozzle 21 is designed in a pivotable arm 35, the position of which can be adjusted from the outside through a spindle 36. During the adjustment, the nozzle 21 is moved along a circular arc and can be placed at the desired distance from the attachment point of the nozzle closing plate 34 °g, thereby freeing the nozzle opening for a given inclined position for the nozzle closing plate 22 to a greater or lesser extent, depending on how far the nozzle is from the nozzle closing plate attachment point.

Claims (4)

1. Pressure control valve for regulating the control pressure on a multi-cylinder refrigeration compressor slide control valve to relieve a number of cylinders corresponding to the immediate cooling demand, which pressure control valve has a nozzle standing in connection with the control pressure on the slide control valve, which can be opened and closed using a bellows, if of internal pressure dependent on the compressor's suction pressure can be counteracted by an adjustable spring to determine the desired cold range, characterized in that a disc-shaped nozzle closing plate (22) is mounted in such a way in relation to the bellows (10), that in the event of axial impact as a result of a contraction of the bellows (10) will position itself obliquely in relation to the nozzle (21), as well as in that the place where the nozzle closing plate (22) must interact with the nozzle (21) can be changed by turning the nozzle closing plate (22) and the nozzle (21) in relation to each other. 2. Pressure control valve according to claim 1, characterized in that the nozzle closing plate (22) with its center is axially and rotatably fixedly connected to the bellows (10), and that the nozzle closing plate is further connected at mutually axially spaced locations with a rotatable connection with the bellows (10) ,, but not axially displaceable part by means of leaf springs (29, 30)• 3- Pressure control valve according to claim 1, characterized in that the nozzle closing plate (22) is resilient and with its center axially and rotationally firmly connected to the bellows (10), and that a single place on the edge of the nozzle closing plate (22) is attached to one with the bellows (10) ) rotating part. 4. Pressure control valve according to claim 1, characterized in that the nozzle closing plate (22) is a spring axle and fixed at a location (34) at some distance from the connection point with the bellows (10), and that the distance of the nozzle (21) from the closing plate (22) fixing point ( 34) is adjustable, preferably in that the nozzle (21) is placed on an arm (35) which can be rotated in relation to the nozzle closing plate (22)•