RU2095777C1 - Device for taking isokinetic samples of working medium - Google Patents

Abstract

FIELD: examination and analysis of substances. SUBSTANCE: device has at least one sampling hole and power cylinder with rod, stop valve coupled to power cylinder and manufactured for communication with sampling hole. Device is provided with probe coupled to vacant end of power cylinder rod. Probe is mounted for axial movement from device through stop valve for introduction into working medium flow through sampling hole. Probe has at least one intake hole communicating with channel located inside power cylinder rod. Rod is made as two internal and external tubes positioned coaxially. Probe is mounted on internal tube. Auxiliary intake hole is provided on vacant end of external tube. Intake holes in probe and in tubular rod are shifted relative to each other through angle of 180 deg. Intake hole in probe faces the side opposite to working medium flow in order to take preset portion of medium flow into internal tube. EFFECT: improved sampling process. 2 cl, 5 dwg

Description

 The invention relates to a device for sampling isokinetic samples of a working medium flowing under high pressure in a tank, separator, heat exchanger or other containers or pipes.

 To describe the structure of the gas stream during various production processes, it is necessary to obtain isokinetic gas samples.

 A device for sampling isokinetic samples of a working medium under high pressure in an apparatus for a working medium having at least one sampling hole containing a power cylinder with a rod, a shut-off valve connected to the power cylinder and configured to connect to the specified hole for sampling, and a probe associated with the free end of the ram cylinder installed with the possibility of axial movement from the device through the shut-off valve for input through the sampling port Rob in the flow of the working medium and having at least one receiving hole in communication with the channel inside the rod of the cylinder (US, patent, N 4294124, CL G 01 N 1/10, publ. 1981). Using this known device, samples of the working medium are taken in the form of a predetermined part of the working fluid stream, as well as samples in the form of a part of the flow having the opposite direction, using two separate tubes, each of which is equipped with a receiving hole. However, it is very important to make the cross section of the input part of the device at the point of sampling as small as possible, while two separate tubes of the known device occupy a significant amount in the transverse plane.

 The technical result of the invention is the creation of a more compact part of the device introduced into the flow of the working medium, while reducing the cross section of this part introduced into the reservoir of the device.

To achieve a technical result in a device for sampling isikinetic samples of a working medium under high pressure in a apparatus for a working medium having at least one sampling hole containing a power cylinder with a rod, a shut-off valve connected to the power cylinder and configured to connection with the specified hole for sampling, and a probe associated with the free end of the rod of the power cylinder, mounted with the possibility of axial movement from the device through the shut-off valve for the input through the hole for sampling into the flow of the working medium and having at least one receiving hole in communication with the channel inside the rod of the power cylinder, according to the invention, the rod is made in the form of two coaxially mounted inner and outer tubes, the probe is mounted on the inner tube, and the free end of the outer tube has an additional receiving hole. The receiving hole in the probe and the receiving hole in the tubular rod are offset from each other by an angle of 180 ^o C, and the receiving hole in the probe faces the opposite side of the working fluid flow for the intake of a given part of the flow into the inner tube.

 Figure 1 shows a General view of the device in its original position; figure 2 is the same in the working position; figure 3 probe; figure 4 embodiment of the probe; figure 5 probe of figure 4 in plan.

 Figure 1 shows the apparatus for the working medium 1 in the form of a tank, centrifuge, heat exchanger or other similar container or pipe, where there is a flow of the working medium, the structure of which must be investigated by sampling using this device.

 The apparatus for the working medium 1 has at least one sampling hole in the form of a connecting socket 2, in which a fitting with a tapered shank 3, 4 and a nut 5 is installed. The shank 4 is screwed into the socket 2 of the apparatus 1, and the shank 3 is screwed into an internal thread part of the pipe of the shut-off valve body 6, made, for example, in the form of a ball valve. The valve 6 is equipped with a control handle 7 and is connected by a threaded connection to the end fitting 8 of the power cylinder body 9. A threaded nut 10 is installed at the opposite end of the power cylinder body 9. A piston 11 and a rod made in the form of two coaxially installed inner and outer tubes 12 and 13, respectively.

 The connection of the ball shut-off valve 6 with the socket 2 is carried out with the valve closed (figure 1).

 The circumferential surface of the piston 11 is sealed along the inner surface of the cylinder 9 by means of O-rings and O-rings. In a preferred embodiment, the stroke of the piston 11 is variable.

 The outer tube 13 has an annular flange 14 radially facing inward through which the outer end of the inner tube 12 of the piston rod 11 passes, the joint between these tubes is hermetically sealed.

 In any case, the piston stroke 11 (preferably variable) must be such that the working (left, on which, as described below, probe) end of the piston rod 11, while in the working position shown in Fig. 1, is located in front of the closed ball valve 6, and in the working position, as shown in figure 2, behind the open ball valve 6 to enable traverse the flow of the working medium in its cross section.

 The device can be used with removable probes 15 (Fig. 3) and 16 (Figs. 4 and 5) having various receiving openings. When replacing probes 15 or 16, the sampling ports will also be changed.

 Each probe 15 and 16 can be secured by any detachable connection to the free end of the inner tube 12 of the piston rod 11. In FIG. 3-5 depicts a bayonet connection 17.

 Each probe 15 and 16 has at least one external receiving hole 18 connected to a channel 19 in communication with the inner tube 12 of the piston rod 11.

 The receiving hole 18 of the probe 15 is made with the possibility of sampling both in the middle of the cross section of the flow of the working medium, and near the inner wall of the apparatus 1.

 The receiving hole 18 of the probe 16 (FIGS. 4 and 5), in addition, is made with the possibility of isokinetic samples in the immediate vicinity of the inner wall of the apparatus 1 due to the fact that the extreme edge 20 of the receiving hole coincides with the extreme point of the probe. Thus, it is possible to "scrape" the sample gas from the inner wall of the apparatus 1 by means of a probe with such a receiving opening.

Similarly, the outer tube 13 of the piston rod 11 has a receiving hole 21, which, as shown in FIG. 3-5, is located at an angle of 180 ^o C relative to the hole 18 of the probes 15 and 16. The receiving hole 21 of the outer tube 13 of the piston rod 11 may have a diameter, for example 5 mm

 Opposite the probes 15 and 16, the end of the inner tube 12 of the piston rod 11 is connected to the valve 6 through a T-adapter 22.

 The annular space between the inner and outer tubes 12 and 13 of the piston rod 11 communicates with the tube 23 in which there is a valve.

 A fitting 24 is installed in the nut 10 for connection with a hydraulic pump to provide controlled reciprocating movement of the piston 11 and, accordingly, its stem through a ball valve 6.

 The device has a valve 25 to relieve pressure or a hydraulic return piston 11 with a rod and a probe 15 or 16. The maximum pressure is, for example, 1500 bar.

 The device operates as follows. After installing the device at the sampling point in socket 2, as shown in FIG. 1, the ball valve 6 is opened and the probe 15 or 16, connected by means of a rod to the piston 11 being tested, is advanced into the fluid flow inside the apparatus 1, while the probe is extended 15 or 16 are chosen as desired and necessary.

The receiving hole 18 of the probe 15 or 16 is positioned against the direction of flow and sampling is performed in the form of a predetermined part of the working fluid flow passing through the inner tube 12. The receiving hole 21 in the outer tube 13 is offset by an angle of 180 ^° C with respect to the hole 18. Therefore, through it is possible to sample the part of the stream having a reverse direction.

 After the flow rate changes, the piston 11 can be moved back by pumping oil through the valve 25, after which the valve 6 is closed, the pressure is released, the probe 15 or 16 is disconnected, a new probe is installed, the valve 6 is opened and the probe 15 or 16 is inserted into apparatus 1 to a given depth. Next, the sampling cycle is repeated.

Claims (2)

 1. Device for sampling isokinetic samples of a working medium under high pressure in an apparatus for a working medium having at least one sampling hole containing a power cylinder with a rod, a shut-off valve connected to the power cylinder and configured to connect to the specified a sampling hole, and a probe connected to the free end of the ram cylinder installed axially from the device through a shut-off valve to enter through the sampling hole into the flow of the working medium and having at least one receiving hole communicating with the channel inside the ram cylinder, characterized in that the rod is made in the form of two coaxially mounted inner and outer tubes, the probe is mounted on the inner tube, and made on the free end of the outer tube additional receiving hole. 2. The device according to claim 1, characterized in that the receiving hole in the probe and the receiving hole in the tubular rod are offset relative to each other by an angle of 180 ^o , and the receiving hole in the probe is facing the opposite side of the working medium flow for collecting a given part of the flow into the inner the receiver.

Images