RU2514871C2 - Tank for moisture precipitation and removal from compressed gases - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to compressed gas treatment. Proposed tank is composed of the body with shell ring whereto welded are some vertical corrugated zinc-plated plates with inclined baffles and drain pipe. Inclined baffles are arranged in height of plates to make the fluid discharge triangular channels. Said baffles are bent at their mid part. Said body has the baffle arranged under bottom baffle to connect adjacent plates. Aforesaid corrugated plates have cut-outs furnished with tabs bent in opposite directions. Note here that said body is coated with solid layer of heat-resistant heat-conducting paste with different-depth sections, the ribs, alternating over its length.

EFFECT: efficient cooling, precipitation and removal.

1 dwg

Description

The invention relates to techniques for deposition and removal of moisture from compressed gases, for example, to remove moisture from compressed air in brake pneumatic systems of the railway industry.

A known tank for the deposition and removal of moisture from compressed gases, including a housing, to the shell of which is attached a series of vertical corrugated plates with inclined partitions installed along the height of the plates and made with channels for draining the liquid, as well as a drainage pipe; the partitions are made curved in the middle part, and the tank is equipped with a jumper installed under the lower partition and connecting adjacent plates (see AS USSR No. 3822849, IPC B01D 45/08, 1981).

The lack of cooling, deposition, and moisture removal from compressed gases (air) is the disadvantage of this tank.

The closest in technical essence to the claimed one is a reservoir for deposition and removal of moisture from compressed gases, including a housing, to the shell of which are attached, for example, a series of vertical corrugated plates with inclined partitions installed along the height of the plates and made with channels for draining liquid, as well as a drainage tube; the partitions are made curved in the middle part, and the tank is equipped with a jumper installed under the lower partition and connecting adjacent plates; the corrugated plates are made of galvanized and form channels having, for example, a triangular shape, and in the corrugated plates there are slots provided with petals bent in opposite directions (see RF patent No. 2192917, IPC B01D 53/26, 2001). This tank was made as a prototype.

The lack of cooling, deposition and removal of moisture from compressed gases (air) is a disadvantage of the prototype.

The claimed invention is aimed at increasing the degree of cooling, deposition and removal of moisture from compressed gases (air); the device comprises: a housing, to the side of which are welded a series of vertical corrugated plates with inclined partitions installed along the height of the plates and made with channels for draining the liquid, as well as a drainage pipe, where the partitions are made curved in the middle part, and the body is equipped with a jumper installed under the lower partition and connecting adjacent plates, galvanized corrugated plates that form channels having a triangular shape, and slots are made in the corrugated plates, provided with petals bent in opposite directions, while the tank body for deposition and removal of moisture from compressed gases is covered with a layer of heat-resistant heat-conducting paste with sections of varying thickness alternating along its length.

Thus, the proposed technical solution differs from the prototype in that it is proposed to cover the tank body with a layer of heat-resistant heat-conducting paste with sections of unequal thickness alternating along the length of the tank body - ribs.

The invention is illustrated in figure 1, which shows a reservoir for the deposition and removal of moisture from compressed gases. The device comprises a housing 1, coated with a layer of heat-resistant heat-conducting paste 5, which along the length of the housing 1 has alternating sections of unequal thickness - trough 6 and ribs 7; a number of vertical corrugated plates with inclined partitions 2 mounted along the height of the plates and made with channels for draining the liquid, and also a drainage pipe 3 are attached to the inner shell of the housing 1 by welding; the partitions are made curved in the middle part, and the tank is equipped with a jumper installed under the lower partition and connecting adjacent plates; the corrugated plates are galvanized and form channels having, for example, a triangular shape, and in the corrugated plates there are slots provided with petals bent in opposite directions; the reservoir for sedimentation and removal of moisture from the compressed gases also includes a purge valve 4.

The device operates as follows. A stream of compressed gas, for example air, containing moisture in the droplet-dispersed state, enters the tank body 1 and passes through winding channels formed by a series of vertical corrugated plates. In a stream of compressed air that meets corrugated plates on its way, moisture is separated, which flows down, entering the channels and then into the drainage pipe. Slots equipped with petals bent in opposite directions provide the destruction of the boundary layer of the injected compressed gas, as a result of which the heat transfer from the gas to the structural elements of the tank increases (intensifies). Thus, the heat transfer coefficient from the compressed gas to the inner shell of the tank body increases. To enhance the cooling effect of compressed gas (air) and increase the heat transfer coefficient from the outer surface of the tank body to the environment, the outer surface of the tank body 1 is coated with a layer of heat-resistant heat-conducting paste, for example, which is an organosilicon material of high reliability with high thermal conductivity and self-adhesive ability. This provides local increases in heat transfer coefficients, which in turn will increase the separation of moisture from the compressed gas due to its more intensive cooling. Consequently, the compressed gas (air) becomes drier.

To increase heat transfer, heat-resistant heat-conducting paste is applied to the tank body 1 in a continuous layer with sections of unequal thickness alternating along the body length (Fig. 1) containing troughs 6 and ribs 7. This will intensify heat transfer with the environment and, as a result, increase the degree of drying of the compressed air.

Compared with the prototype, the degree of deposition and removal of moisture from compressed gases (air) is increased due to improved heat transfer with the environment.

Claims (1)

A reservoir for sedimentation and removal of moisture from compressed gases, comprising a housing, to the shell of which are attached a series of vertical corrugated plates with inclined partitions installed along the height of the plates and made with channels for draining liquid, as well as a drainage pipe where the partitions are made curved in the middle part and the case is equipped with a jumper installed under the lower partition and connecting adjacent plates, galvanized corrugated plates that form channels having a triangular shape, and in th e plates slits provided with petals bent away in opposite directions, characterized in that the housing is covered by a continuous layer of a heat-resistant heat-conductive pastes with alternating over its length portions of different thickness - ribs.