RU2351387C2 - Cartridge for air dehumidifier - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: proposed invention relates to automotive air systems. Cartridge with air dehumidifier has base 12 with inlet 20 and outlet 18 holes and casing 14 jointed to said base 12 to confine the space containing air dehumidifier 26 and filter 38. Humid airflow 84 and that of oily mist 86 enters the cartridge via said inlet 20, passes through filter 38 to get cleared of oil drops therein, air dehumidifier 26 to get into outlet 18. In reactivating the cartridge, scavenging airflow 90 comes in through outlet 18, passes through air dehumidifier 26 to get into filter 38. The proposed cartridge incorporates a valve that allows a portion of scavenging air flow to bypass the filter.

EFFECT: bypassing flow portion allows entrapping fluid accumulated in sump and reducing consumption of power for air dehumidifier reactivation.

29 cl, 9 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a dehumidifier for vehicles and, in particular, to a cartridge or cartridge with a desiccant for such a dehumidifier.

State of the art

The use of an apparatus for drying air, hereinafter referred to as a dehumidifier, in automobile air systems is well known. Typically, a dehumidifier is located between an air source, such as a compressor, and a reservoir. The dehumidifier contains a moisture-absorbing substance, such as silica gel, which removes moisture from the air coming from the compressor to prevent the moisture from penetrating further into the car’s air system, where it can damage the air system components over time. In order to remove moisture accumulated in the desiccant, the dehumidifier is periodically blown into the atmosphere with dry air from the tank. The dehumidifier is purged, as a rule, at a time when the compressor is not working, and the tank does not require a significant supply of dry air. The moisture-absorbing substance is usually contained in a portable container or cartridge, hereinafter referred to as a cartridge, which is installed as a replaceable element in a dehumidifier. The cartridge must be replaced periodically due to a decrease in the effectiveness of the desiccant over time.

It is known that the air coming from the compressor contains a mist consisting of very small droplets of oil. The source of these drops is lubricating oil, which provides reciprocating compressor motion. Oil mist, as a rule, passes through a dehumidifier and then settles in the tank or further in the air system of the car. Although this deposition of oil is much less harmful to the components of the air system than the deposition of moisture, but the deposition of oil can lead to problems over time, such as narrowing narrow passages in the components of the air system or the destruction of elastomeric gaskets.

Disclosure of invention

An object of the present invention is to provide an improved air dryer to prevent the passage of oil through it.

According to a first aspect of the present invention, there is provided a cartridge with a desiccant for an air dryer having a base with inlet and outlet openings and a casing connected to the base and defining a cavity containing a filter and a desiccant, the filter being installed upstream of the desiccant so that during normal operation of the cartridge, the fluid flow entering the cartridge through the inlet passes through the filter, and then through the desiccant until it enters the outlet, and during uvki cartridge purge flow entering through the outlet passes through the desiccant before entering the filter, wherein the cartridge is provided with a valve providing bypass filter part of the purge stream.

Due to the presence of the valve, the entire fluid flow entering the cartridge during normal operation is directed through the filter before reaching the desiccant, while the purge flow is separated so that part of the purge flow passes through the filter in the opposite direction and the rest of the purge flow bypasses the filter .

The valve preferably comprises a slide valve which is locked into position by the flow of fluid entering the cartridge through the inlet, thereby preventing the passage of fluid through the valve. The spool can be made in the form of an elastic element. In such an embodiment, the elastic member may have a proximal portion attached to the cartridge and a movable distal portion. An elastic element may be located at the bottom of the cartridge between the filter and the base. Alternatively, the valve is provided with a channel in which the movable valve spool is located.

Further, the cartridge may contain a sump communicating with the filter. The sump is designed to collect the fluid removed from the stream flowing into the cartridge. Preferably, the sump is located close to the valve, as a result of which the purge stream guided through the valve carries away the liquid accumulated in the sump.

According to a second aspect of the present invention, there is provided a cartridge with a desiccant for an air dryer having a base with inlet and outlet openings, a casing connected to the base and defining a cavity containing a filter, a container in which the desiccant is placed, and a spring mounted to hold the container and filter against the base, and the filter is located between the container and the base, so that at least part of the force exerted by the spring on the container and the desiccant is transmitted to the base through the filter .

Thus, the present invention provides a desiccant cartridge in which the desiccant container and the filter are arranged one above the other, and the force exerted by the spring is used to fix the container and the filter relative to each other and to the base.

In such an embodiment, the filter may comprise a structural element on which filter material is mounted. Alternatively, the filter material may be mounted on more than one component. In a preferred embodiment, the filter has a cylindrical shape and contains an annular structural element supporting the filter material, respectively arranged in an annular manner. Preferably, the structural element is located radially inside the filter material.

The desiccant container may have a substantially cylindrical shape. In such an embodiment, the container may at least partially fit into the filter ring. The container may consist of a first part, the diameter of which is less than the diameter of the filter ring, and a second part, the diameter of which is larger than the diameter of the ring. In such an embodiment, the transition section of the container between the first and second parts may form a receptacle for receiving a filter.

According to a third aspect of the present invention, there is provided a support member for a cartridge with a desiccant, comprising an upper part adapted to receive a cartridge filter and a lower part adapted to support the cartridge base, the lower part comprising a channel and locking means for opening and closing said channel .

In a preferred embodiment, the upper part of the support element has a slot for installing and holding a filter therein. The socket may have one or more connecting elements, which during use fix the filter relative to the support element. The connecting elements may have one or more protrusions. Said protrusions may be made in the form of one or more spring-loaded pins. In addition, the nest may have a contour.

The channel may be a hole in the lower part of the support element. The locking means may comprise an elastic element overlapping said opening. The elastic element may be in the form of a skirt or rib of elastic plastic. The lower part may have several channels. In this embodiment, the channels may be formed by a series of holes. In an alternative embodiment, the lower part has a number of legs resting in the process of use on the base of the cartridge, the channels being located between these legs. The support element may have one or more connecting elements, engaging in use with one or more elements of the base of the cartridge.

The support element is preferably made of plastic by injection molding. The elastic skirt or rib is preferably cast integrally with the support element.

According to a fourth aspect of the present invention, there is provided a filter device mounted between a cartridge with a desiccant and an air dryer housing, comprising a housing with inlet and outlet openings and a filter located in the housing between the inlet and outlet openings, and in the region of the inlet and outlet openings, the housing is provided with seals to provide in the process of using a tight connection between the filter and the cartridge and the air dryer housing.

The filter device described above is a separate component that can be integrated into the air dryer system to filter the incoming fluid until the medium reaches the desiccant in the air dryer cartridge. During normal operation of the filter device and cartridge, the fluid entering the filter device through the inlet passes through the filter, and then through the outlet enters the cartridge. When purging the cartridge and filter device, the purge stream enters the outlet and passes through the filter before exiting the filter device through the inlet. The filter performs a useful function by removing particulate matter, oil mist and moisture from the incoming air.

In a preferred embodiment, the filter device is provided with a sump, in which flows the liquid removed by the filter from the fluid stream. In addition, the filter device is preferably equipped with a valve allowing the filter to bypass part of the purge stream.

Due to the presence of the valve, the entire fluid flow entering the filter device during normal operation is directed through the filter before reaching the desiccant, while the purge stream is separated so that part of the purge stream passes through the filter in the opposite direction, and the rest of the purge stream bypasses filter.

The valve preferably comprises a slide valve which is locked into position by the flow of fluid entering the filter device through the inlet, thereby preventing the passage of flow through the valve. The valve may have a channel in which a movable valve spool is mounted.

Brief Description of the Drawings

Embodiments of the present invention are described below with reference to the accompanying drawings, where:

figure 1 shows a sectional side view of the cartridge for a dehumidifier in accordance with the present invention;

on figa shows in partial section the socket of the cartridge of figure 1;

Fig. 2b is a partial sectional view of an alternative cartridge socket;

figure 3 shows a closeup in section of the lower part of the cartridge of figure 1;

figure 4 presents another closeup image in section of the lower part of the cartridge of figure 1;

5 is a partial cross-sectional view of a cartridge for an air dryer in accordance with an alternative embodiment of the present invention;

on figa shows a side view of the valve cartridge for the dehumidifier shown in figure 5;

Fig.6b is a perspective view of the valve seat of Fig.6a;

7 and 8 are a cross-sectional view of a filtering device according to another aspect of the present invention; and

Fig. 9 is a schematic sectional view of another embodiment of a cartridge for an air dryer according to the present invention.

The implementation of the invention

Let us first turn to figure 1, which shows in section a cartridge with a desiccant, made in accordance with the present invention and denoted as a whole by the number 10. The cartridge 10 contains a support element 12, a casing 14 and an inner bowl 16. The support element 12 has a Central hole 18 surrounded by a series of additional openings 20. The central hole 18 is threaded so that the cartridge 10 as a whole can be screwed into the mating threaded sleeve in the air dryer housing. The support element 12 is equipped with an annular sealing plate 22, in which an elastomeric sealing gasket 24 is placed. The gasket 24 ensures the tightness of the connection of the cartridge 10 with the air dryer housing.

In the inner bowl 16 is a matrix 26 with a desiccant, which contains a desiccant, for example silica gel granules. The inner bowl 16 contains a perforated base 28 having a vertical wall 30. To prevent the medium from penetrating through the gap between the support element 12 and the perforated base 28 of the bowl 16, a toroidal gasket 31 is laid between them. As can be seen in FIG. 1, the wall has a stepped shape, so that the cup 16 has a lower part 32, the diameter of which is smaller than the diameter of the upper part 34. Due to the smaller diameter of the lower part 32, there is an annular space 36 between the lower part 32 and the casing 14, in which the rings are placed filter 38. The upper end 40 of the filter 38 enters the seal 42 abutting against the protrusion 44 of the bowl 16, and the lower end 46, which enters the seal 48, abuts against the seat 50.

In the cartridge 10 there is further a perforated cover 52, which enters the upper part 34 of the bowl 16, and a spring 54 located between the cover 52 and the casing 14. The spring 54 is inserted into the socket 56 of the corresponding shape in the cover 52 and abuts the washer 55.

The filter 38 comprises an annular tube of filter material 78 attached to a perforated sleeve 80. The sleeve 80 serves as a power element that transfers the load applied to the filter 38 by a spring 54, a washer 55, a cap 52 and a bowl 16 to the socket 50. The filter material may comprise several layers of a porous substance and is designed in such a way that it provides both the coalescence of liquid droplets, for example, oil or water, and the capture of solid particles trapped in the cartridge 10. Seals 42, 48 can be of any suitable type, for example er, it may be elastomeric or compressible toroidal gasket type seal cuff. In the depicted embodiment, the seals 42, 48 are located on the holders, covering the ends 40, 46 of the filter 38. The bowl 16 has a series of protrusions 82 (one of which is shown in the drawing) arranged at a certain pitch around the circle, which are connected to the upper seal holder, holding the filter 38 in bowl 16.

Socket 50 is shown in close-up in FIG. 2a. It contains an annular base 58, having a straight wall 60 on the inside. The outer edge of the base 58 consists of a series of vertical pins 62, each of which has a protrusion 64 at the end. In the depicted embodiment, the annular base 58 is almost flat, however, the base can be made so to facilitate the installation and location relative to it of the filter 38. For example, the base 58 may have one or more elements, such as protrusions, mating with the corresponding elements of the filter 38. The base 58 may have shaped contour, for example, convex or concave, to facilitate the installation and location of the filter 38 relative to it. tabs 68. Similar tabs 70 with a corresponding step go along the inner edge of the lower side of the base 58. As can be seen in figure 1, the tabs 68, 70 of the socket 50 abut against the support element 12 and thereby determine the number of holes for the duct the medium between the tabs 68, 70, the annular base 58 and the support element 12.

The nest 50 further has a sealing element 72 laid along the annular rib 66. The sealing element 72 has an elastic protrusion 74, which, when viewed in section, is directed radially inward and downward relative to the rib. The sealing element 72 is usually made of elastic plastic, for example neoprene rubber. As can be seen in FIG. 2, the outer edge 76 of the protrusion 74 extends beneath the lower ends of the legs 68 of the rib 66. As will be described in more detail below, the sealing element can be used during operation to close openings for the passage of the medium made between the legs 68 of the rib. Socket 50 can be made of plastic by injection molding with the addition of a sealing element 72 during the next casting operation. The following casting operation can be used to form another, additional seal to the annular base 58. Another sealing gasket 77, shown in broken lines, is made of the same material as the sealing element 72, and forms a seal between the filter 38 and the socket 50. Sealing the gasket 77 is connected to the sealing element 72 by a series of through holes 59 in the annular base 58.

On fig.2b shows an alternative socket, indicated by the whole number 51. Elements common to the elements depicted in figa, are indicated by the same numbers. The socket 51 is characterized in that it has a series of inwardly directed protrusions 61 (only one of them is shown) extending from the wall 60. The protrusions 61 have points 63 that are connected to the support element 12 of the cartridge 10, catching on the edges of the additional holes 20. The engagement of the protrusions 61 and additional holes 20 prevents the axial displacement of the socket 51 relative to the support element 12 in the event of a transverse differential pressure. Preventing axial misalignment reduces the likelihood that the sealing element 72 will slide under the rib 66. The socket 51 is shown with pins 62, however, they are optional and can be discarded.

During operation, the cartridge 10 is attached to the casing of the apparatus for drying air (not shown) so that incoming moist air (shown by arrow 84) and oil mist (shown by arrow 86) from the compressor enter the cartridge 10 through additional openings 20. Wet air and oil the mist passes in the middle of the base 28 of the bowl 16 into the filter 38. When passing through the filter material 78, a significant part of the oil mist is removed from the air stream. Filter material 78 removes oil mist through coalescence — the coalescence of individual droplets that form fog into large droplets that are not held in the air stream passing through filter material 78. These large droplets are either retained by filter material 78 or flow out of filter material 78, as shown by arrow 86, in the regional sump 88, located between the supporting element 12 of the cartridge, the socket 50 and the casing 14. The filter material 78 simultaneously removes some of the moisture contained in the incoming ozduhe by similar merging drops. Like oil mist, water droplets in the incoming air merge and either are trapped in the filter material 78 or flow into the sump 88.

Figure 3 shows in an enlarged view the lower part of the cartridge 10 with the sealing element 72 of the socket 50. With a normal flow of moist air and oil mist through the filter 38, a differential pressure occurs on the filter 38. This differential pressure is used by the sealing member 72 to provide a tight seal between the supporting member 12 and the underside of the receptacle 50, as shown in the drawing. The presence of such a tight seal forces all incoming moist air and oil mist to pass through the filter 38.

After passing through the filter 38, the incoming air with the remaining moisture in it is directed upward between the inner wall of the casing 14 and the bowl 16, before descending through the matrix 26 with a desiccant, where moisture is removed and retained by the material forming the matrix 26. Further condensation of moisture from the air may occur when air passes between the inner wall of the casing 14 and the bowl 16. The cleaned and dried air then passes through a wool pad 105 covering the base of the bowl 16 and the central hole 18 of the cartridge 10, into the app arat for draining the air, and further into the reservoir (not shown).

As mentioned above, the desiccant in cartridge 10 must be periodically restored with dry air to prevent it from saturated with moisture and loss of efficiency. The flow of dry regeneration air through the cartridge, as shown by arrow 90, flows in the opposite direction to that shown for moist air and oil mist. Dry regeneration air from the reservoir enters the cartridge 10 through the central hole 18 and then into the bowl 16, passing through the wool pad 105 and the matrix 26 with a desiccant. The humidified air now leaves the bowl 16 through the lid 52 and passes between the bowl 16 and the casing 14 to the filter 38. Here, the regeneration stream is separated, so that part of it passes through the filter 38, and the rest of the stream bypasses the filter 38 and is used to remove water and oil, accumulated in the sump 88, as described below.

Figure 4 shows in an enlarged view the lower part of the cartridge 10, including the sealing element 72 of the socket 50, during the passage of the regeneration stream. The part of the regeneration stream 90, which reaches the sealing element 72, raises the element 72, diverting it from the support element 12. Therefore, the regeneration stream 90 can pass under the sealing element 72, while taking away with it the liquid accumulated in the sump 88, as shown by arrow 92. The stream regeneration 90 and trapped liquid 92 exit the cartridge 10 through an additional opening 20 into the atmosphere. The part of the regeneration stream 90, which passes through the filter 38, captures the moisture accumulated in the filter material 78, as well as particles of solid matter, and similarly enters the atmosphere through the additional hole 20. As can be seen in figure 4, the separated parts of the regeneration stream 90 are connected between each other before entering the additional hole 20.

Referring now to FIG. 5, an alternative embodiment of a desiccant cartridge for a dehumidifier according to an aspect of the invention and indicated by a common number 110 is shown. The cartridge 110 has a base 112 to which a casing 114 is connected via a sealing pad 116. B the illustrated embodiment, the sealing pad 116 is connected to the base 112 through a series of pins 118 (only one pin is shown in the drawing) that fit into the corresponding through holes 120 of the base 112. To fasten the casing 114 to 112, the edge 122 of the casing 114 extends into the annular recess 124 of the sealing pad 116. The recess is bent so as to hold the casing 114. The sealing pad 116 also serves as a support for the sealing element 126, which during operation provides a tight seal between the cartridge 110 and the air dryer housing ( not shown).

The base 112, the casing 114 and the sealing pad 116 define a cavity in which the desiccant matrix 130 is located. In the matrix 130 with a desiccant there is an almost cylindrical support element 132, consisting of a section 134 of a larger diameter and a section 136 of a smaller diameter. Section 134 of a larger diameter serves to accommodate a matrix 130 with a desiccant in the upper part of the cavity, and a section of smaller diameter limits the channel 138, located coaxially with the hole 140 located in the center of the base 112. The section 136 of the smaller diameter of the support element 132 has a heel 142, which is supported on the toroidal seal 144 on the base 112. The annular inlet chamber 146 is limited by the base 112, the casing 114 and the portion 136 of the smaller diameter of the support element 132. The size of the portion 134 of the larger diameter of the support element 132 you braned such that between it and the casing 114 there is an annular passage 148. An annular passage 148 connects the inlet chamber 146 with a space 150 above the matrix 130 with a desiccant. The support member 132 and the desiccant matrix 130 are held in place by a spring 128 acting on the perforated cover 129 covering the matrix 130 and the casing 114.

The cartridge 110 is also equipped with a filter device with a common designation 152, which is located in the casing 114 between the base 112 and the support element 132. The device 152 includes a filter element 154, a lower support ring 156 of the filter element and an upper support ring 157 of the filter element. The filter element 154 and the support rings 156, 157 divide the inlet chamber 146 into first and second parts 158, 160, respectively. The sealing elements 162, 164 are arranged so as to prevent the flow through the space between the device 152, the support element 132 and the casing 114. The support ring 156 further has a sump 166 located in the second part 160 of the inlet chamber 146. The sump 166 is provided with a drain valve 168, which, under certain operating conditions, discharges the liquid accumulated in the sump 166 into the first part 158 of the inlet amers 146.

The filter element 154 contains a number of layers with a filter medium. The material of each layer may consist, for example, of glass microfibre or a suitable plastic. The layers can be closely adjacent to each other or, alternatively, separated by appropriate gaskets. The design of such a filter element has a perforated support portion to which a filter medium is attached.

The cartridge 110 is preferably equipped with a pressure relief device that acts in the event of a clogging of the filter element 154. The sealing element 162 between the device 152 and the support element 132 can be designed so that if the pressure drop over it exceeds the set value, it will cease to function. Alternatively, the support member 132 may extend away from the filter element 154, overcoming the resistance of the spring 128 and creating a flow passage.

6a and 6b, the drain valve 168 is shown in close-up. The inlet 170 of the valve 168 is in fluid communication with the sump 166, and the outlet 173 is in fluid communication with the first part 158 of the inlet chamber 146. Between the inlet 170 and the outlet 172 there is a valve chamber 174 containing a spool 176 having in this embodiment a substantially spherical form. Further, the chamber has a seat 178 for spool 176 located in the inlet 170 and a series of bypass channels 180 adjacent to the outlet 172. The spool 176 moves longitudinally in the valve chamber 174, as shown by arrow 182. The outlet 172 is surrounded by teeth 173 so that the spool 176 could not lock it. In the depicted embodiment, the valve chamber 174 is located almost perpendicular to the base 112 of the cartridge 110. It should be noted that such a device maximizes the influence of gravity on the spool 176 and helps to empty the sump 166 during periods when the compressor is stopped. It should be noted that in an alternative embodiment, the valve chamber 176 may be inclined.

We turn to the description of the action of the cartridge 110. It is clear that during operation, the cartridge 110 is attached to the housing of the air dryer. Attachment is usually accomplished by screwing the threaded portion of the base 112 into the corresponding threaded portion of the air dryer housing. When the air system compressor is operating under load, moist and contaminated air, together with oil mist, enters the first part 158 of the inlet chamber 146 through openings 120 in the base. Wet air and oil mist then pass through the filter element 154 into the second part 160 of the inlet chamber 146. Air cannot pass through the drain valve 168, since the pressure drop across the valve 168 presses the spool 176 against the seat 178, thereby closing the inlet 170 The air passing into the second part 160 of the inlet chamber 146 then flows through the annular channel 148 into the space 150 above the desiccant matrix 130. Then, air passes through a desiccant matrix 130, where moisture contained in the air is removed. Then dry air leaves the cartridge 110 through the channel 138 and the hole 140.

It should be borne in mind that the air entering the first part 158 of the inlet chamber 146 from the compressor is saturated with water and contaminated with oil mist from the compressor and solid particles, such as dust. The filter element 154 causes coalescence of a significant portion of the droplets of oil mist, so that they fall into the sump 166, and traps the particles of solid matter. As described above with respect to the first embodiment, the filter element 154 causes coalescence of a portion of the water contained in the incoming air. The released water and oil are initially held by the filter element 154, and then discharged into the sump 166. Further condensation may occur in the annular channel 148 as the air cools. This condensate can drain along the inner wall of the casing 114 into the sump 166.

As described above, the coalesced oil and water remain in the sump 166 while the drain valve 168 is closed. The drain valve 168 opens when the pressure differential across it equalizes or changes sign. The pressure differential is equalized when the compressor stops working, and therefore, the air stops flowing into the inlet chamber 146. The force pressing the spool 176 against the seat 178 ceases to act, and the spool 176 is lowered by gravity to the outlet 172. Now, the liquid that has accumulated in the sump 166, can pass through the valve chamber 174 to the outlet 172 through the bypass channels 180. An annular drain 184 is provided at the base 112, which is in fluid communication with through holes 120 at the base 112.

The change in sign of the differential pressure across valve 168 occurs during regeneration of the matrix 130 with a desiccant when dry air is blown through the cartridge 110 in the opposite direction. Valve spool 176 moves as described above under pressure applied to valve inlet 170. It should be noted that the liquid accumulated in the sump 166 is pushed through the valve 168 into the annular drain 184, and then out through the holes 120 in the cartridge 110. The valve 168 is designed so that not all dry air can pass through it, as a result of which part of the dry air is forced to pass through a filter 154. As described above, water and oil trapped in the filter 154 are captured, which are then removed to the atmosphere.

Turning now to FIGS. 7 and 8, the following embodiment of the present invention is depicted. The components common with the components of the embodiment depicted in FIGS. 5-6b are denoted by the same numbers. The embodiment of FIGS. 7 and 8 is characterized in that the filter device 152 is housed in a separate housing 186 located between the air dryer housing 188 and the cartridge 190 containing a desiccant. The housing 186 includes a filter element 154, a sump 166, a drain valve 168 and limits two parts 158, 160 of the inlet chamber 146. The filter element 154 is held in the housing by an upper plate 187. In the illustrated embodiment, the compressive force between the cartridge 190 and the air dryer housing 188 is transmitted through an external the wall of the housing 186. It should be noted that in an alternative embodiment, this force can be transmitted through the upper plate 187 and the filter element 154. In this embodiment, the filter element is reinforced so as to absorb the force given through it, without deformation or damage. Accordingly, the design of the filter element 154 may be similar to that shown in FIG. 1, i.e. contain one or more structural elements on which the filter material is placed. The housing 186 has an annular shape with a central hole into which the hollow protrusion 192 of the housing 188 enters during operation of the device. At the end of the protrusion 192 there is a threaded portion 194 connected to the mating threaded portion 196 of the cartridge base 112.

During operation, the housing 186 is sandwiched between the cartridge 190 and the housing 188. The sealing rings 126, 198, 200, 202 provide a tight seal to the corresponding components 186, 188, 190. The drain valve has the same design as the valve in the embodiment shown in FIG. 5 -6b, namely, a slide valve moving under the influence of a differential pressure on it, and a closing valve 168 during normal air flow through the cartridge 190 and an opening valve either under the action of gravity when the compressor is not working, or under the action of a regeneration flow through the cartridge 190.

When the device is operating, air from the compressor enters the first part 158 of the inlet chamber 146 through the passage 204 in the air dryer housing 188, as shown by arrows 206. The compressed air then passes through the filter element 154 into the second part 160 of the inlet chamber 146. As before, the oil and water that has undergone coalescence in the filter element 154 can be discharged into the sump 166 at the base of the second part 160. Then, compressed air passes through the inlet 120 into the cartridge 190, where it is dried in the usual way using a desiccant 130. Sump 166 op rozhnyaetsya either by gravity when the air supply of the compressor is stopped, or the reverse flow of dry air through the cartridge 190 during regeneration of the desiccant. This second case is depicted in FIG. 8 by arrows 208. The fluid from the sump 166 is directed into the channel 204 and then released into the atmosphere through a vent (not shown) in the air dryer housing 188. As before, the dry regeneration air stream is divided between the filter element 154 and the drain valve 168. The part passing through the filter element 154 entrains liquid and solid particles trapped in the material of the filter element 154. The part of the regeneration stream that passes through the drain valve 168, carries away the fluid accumulated in the sump 166.

The filter device 152 shown in FIGS. 7 and 8 can be used in combination with the filter cartridge of the type described with reference to FIGS. 1-6b to further remove moisture and foreign particles. Alternatively, filter device 152 may be used in combination with a conventional cartridge containing only a desiccant.

Consider now figure 9, which shows a cartridge with a desiccant, indicated by the general number 210 in accordance with the following embodiment of the present invention. The cartridge 210 comprises a base 212 and a casing 214 defining a cavity 216 located between them. A cavity 218 with a desiccant and a filter device 220 for retaining contaminants are placed in the cavity 216. The device 220 includes a first filter layer 222, a second filter layer 224, a settler 226, a channel 228 and a drain valve 230. The cartridge 210 further comprises a check valve 232 located between the desiccant matrix 218 and a filter device 220 for trapping pollutants, and a desiccant regeneration channel 234 and a drain valve 236 desiccant regeneration.

During operation, air from the compressor is directed to the cartridge 210 in the usual way, as shown by arrows 240. Air enters through an annular channel 238, limited on one side by a matrix 218 with a desiccant and filter device 220 to trap pollutants, and on the other hand, by a casing 214, the upper part of the cavity 216, and then sequentially passes through the filter layers 222, 224. It should be noted that between the layers 222, 224 there is a non-return valve 232. Oil and moisture removed from the incoming air flow into the sump 226. Then the air passes through the matrix 218 with a desiccant, where the remaining moisture is removed from it. Then, practically dry air exits the cartridge 210 through the outlet 242 in the base 212.

The regeneration stream through the cartridge 210 is indicated by arrows 244. Dry air from the reservoir enters the cartridge 210 through the outlet 242 and passes through the desiccant matrix 218, releasing moisture accumulated in it. Most of this already moist air enters the regeneration channel 234 and is removed through the drain valve 236 into the annular channel 238. A part of the moist regeneration air passes through the check valve 232 to the sump 226 and displaces the accumulated liquid through the channel 228 and the 230 V drain valve. annular channel 238. Humid air and moisture from the sump 226 are discharged into the atmosphere, as shown by arrows 246, into the atmosphere through a vent in the air dryer housing (not shown).

Claims (29)

1. Cartridge with a desiccant for a dehumidifier having a base with inlet and outlet openings and a casing connected to the base and restricting a cavity containing a filter and a desiccant, the filter being installed upstream of the desiccant so that during normal operation of the cartridge there is a fluid flow entering the cartridge through the inlet passes through the filter, and then through the desiccant until it enters the outlet, and during the purge of the cartridge, the purge flow entering through the outlet o the bore passes through the desiccant until it enters the filter, while the cartridge is equipped with a valve that allows the filter to bypass part of the purge stream. 2. The cartridge according to claim 1, characterized in that the valve comprises a slide valve, which is translated into the locking position by the flow of fluid entering the cartridge through the inlet, thereby preventing the passage of fluid through the valve. 3. The cartridge according to claim 2, characterized in that the valve spool is made in the form of an elastic element. 4. The cartridge according to claim 3, characterized in that the elastic element has a proximal part attached to the cartridge and a movable distal part. 5. The cartridge according to claim 3, characterized in that the elastic element is located in the lower part of the cartridge between the filter and the base. 6. The cartridge according to claim 1, characterized in that the valve is provided with a channel in which the movable valve spool is located. 7. The cartridge according to claim 1, characterized in that it contains a sump communicating with the filter. 8. The cartridge according to claim 7, characterized in that the sump is located near the valve, as a result of which the purge stream directed through the valve carries away the liquid accumulated in the sump. 9. The cartridge according to claim 1, characterized in that it further comprises a container in which a desiccant is placed, and a spring mounted with the container and filter pressed against the base, the filter being located between the container and the base, so that the force exerted by the spring on the container and desiccant, is transmitted to the base through a filter. 10. The cartridge according to claim 9, characterized in that the filter contains a structural element on which the filter material is mounted. 11. The cartridge of claim 10, characterized in that the filter has a cylindrical shape and contains an annular structural element that carries the filter material, respectively arranged in an annular manner. 12. The cartridge according to claim 11, characterized in that the structural element is located radially inside the filter material. 13. The cartridge according to claim 11, characterized in that the structural element is located radially outside the filter material. 14. The cartridge according to claim 11, characterized in that the filter contains a number of structural elements. 15. The cartridge according to claim 11, characterized in that the container with the desiccant has a substantially cylindrical shape. 16. The cartridge according to clause 15, wherein the container at least partially enters the filter ring. 17. The cartridge according to clause 15, wherein the container has a first part, the diameter of which is less than the diameter of the filter ring, and a second part, the diameter of which is larger than the diameter of the filter ring. 18. The cartridge according to 17, characterized in that between the first and second parts there is a transition section, which forms a socket for receiving a filter. 19. The cartridge according to claim 1, characterized in that it has a support element comprising an upper part configured to receive a filter and a lower part configured to support the base, the lower part comprising a channel and locking means for opening and closing said channel forming the specified valve. 20. The cartridge according to claim 19, characterized in that the upper part of the support element is provided with a socket for installing and holding a filter in it. 21. The cartridge according to claim 20, characterized in that the socket has one or more connecting elements, which during use fix the filter relative to the support element. 22. The cartridge according to item 21, characterized in that the connecting elements contain one or more protrusions. 23. The cartridge according to item 22, wherein the protrusions are made in the form of one or more spring-loaded pins. 24. The cartridge according to claim 19, characterized in that the channel is formed by a hole in the lower part of the support element. 25. The cartridge according to paragraph 24, wherein the locking means contain an elastic element that overlaps the specified hole. 26. The cartridge according to item 23, wherein the elastic element has the form of a skirt or rib made of elastic plastic. 27. The cartridge according to any one of paragraphs.19-26, characterized in that the lower part is provided with a number of channels. 28. The cartridge according to item 27, wherein the channels are formed by a series of holes. 29. The cartridge according to item 27, wherein the lower part has a number of legs, resting in the process of use on the base of the cartridge, and the channels are located between these legs.

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