CN211179236U - High-efficient sample cooler - Google Patents

Abstract

The utility model relates to a high-efficiency sampling cooler, which comprises a support frame and a heat conduction shell arranged on the support frame, wherein the heat conduction shell is provided with a cooling water inlet and a cooling water outlet; a condensing pipe is arranged in the heat conduction shell, the condensing pipe is of a pipe body structure which is arranged along the inner wall of the heat conduction shell in a ring mode and distributed in a wave shape, one end of the condensing pipe is connected with a sample inlet pipe, the other end of the condensing pipe is connected with a sample outlet pipe, and a sampling groove for receiving a sample is arranged below a sample outlet of the sample outlet pipe; and the outer surface of the heat conduction shell is provided with heat dissipation fins. The utility model discloses strengthen the cooling effect of sample, saved cooling water consumption, the cost is reduced.

Description

High-efficient sample cooler

Technical Field

The utility model relates to a sample cooling arrangement technical field especially relates to a high-efficient sample cooler.

Background

The sampling cooler is mainly used for steam-water testing, sampling and cooling in a boiler room or a power plant, the temperature of most water in the boiler and a thermodynamic system is higher, the high water temperature is inconvenient for sampling and measurement, the water is cooled in the sampling process, and the sample can be cooled to be below 30-40 ℃ generally when the flow is 500-700m L/min.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to prior art's not enough, provide a high-efficient sample cooler, strengthened the cooling effect of sample, saved the cooling water consumption, the cost is reduced.

The utility model is realized by the following technical proposal, and provides a high-efficiency sampling cooler, which comprises a support frame and a heat conduction shell arranged on the support frame, wherein the heat conduction shell is provided with a cooling water inlet and a cooling water outlet; a condensing pipe is arranged in the heat conduction shell, the condensing pipe is of a pipe body structure which is arranged along the inner wall of the heat conduction shell in a ring mode and distributed in a wave shape, one end of the condensing pipe is connected with a sample inlet pipe, the other end of the condensing pipe is connected with a sample outlet pipe, and a sampling groove for receiving a sample is arranged below a sample outlet of the sample outlet pipe; and the outer surface of the heat conduction shell is provided with heat dissipation fins.

Preferably, the condenser pipe includes two inside and outside tubular body structures that set up, the one end of tubular body structure is the introduction port, and the other end is a appearance mouth, and the introduction port of two tubular body structures all is connected with the introduction union coupling, and the appearance mouth of two tubular body structures all is connected with a appearance union coupling. The sample divides two tunnel cooling, can strengthen its cooling effect, and under the certain prerequisite of sample flow requirement promptly, the sample divides two tunnel to walk, can control its velocity of flow and slow down, consequently can increase the heat transfer time of sample and cooling water to improve the heat transfer effect of sample and cooling water, such structure of condenser pipe can make it set up along heat conduction shells inner wall moreover, therefore some heat of sample can the rapid transfer to external environment, reinforcing sample cooling effect.

Preferably, the sample inlet pipe is provided with a second stop valve, and the sample outlet pipe is provided with a third stop valve.

Preferably, the bottom of the sampling groove is connected with a sample discharge pipe. The sampling groove can be convenient for sampling detection, and the sample is discharged from the sampling groove through the sample discharge pipe.

Preferably, the heat dissipation fins are metal flowering fins. The radiating fins can accelerate heat exchange between cooling water in the heat-conducting shell and air outside the heat-conducting shell, enhance the radiating effect of the cooling water, facilitate cooling and save cooling water consumption. The radiating fins are located outside the heat conduction shell and not on the surface of the condensing tube, so that the surface of the condensing tube is smooth and is not easy to deposit and hang dirt, the heat dissipation effect of the condensing tube is ensured by convenient cleaning.

Preferably, the cooling water inlet is connected with a water inlet pipe, the cooling water outlet is connected with a water outlet pipe, and a first stop valve is installed on the water inlet pipe.

Preferably, the cooling water inlet is located at the lower part of the heat-conducting shell, and the cooling water outlet is located at the upper part of the heat-conducting shell.

Preferably, the upper end of the heat-conducting shell is provided with a cover body, the upper end of the heat-conducting shell is provided with a circle of mounting plate, and the mounting plate is connected with the cover body through bolts.

Preferably, the sample inlet pipe and the sample outlet pipe both penetrate through the cover body and are connected with the condensation pipe. When the condenser pipe is cleaned, the condenser pipe is directly taken out together with the cover body for cleaning, and the cleaning is very convenient.

Preferably, the upper end of the condensation pipe is located at the upper part of the heat conduction shell, and the lower end of the condensation pipe is located at the bottom of the heat conduction shell. The length of the condensation pipe is increased as much as possible, so that the cooling effect of the sample is improved.

Preferably, the support frame comprises a support seat and a supporting plate arranged on the support seat, and the supporting plate is fixedly connected with the heat conduction shell.

Preferably, the number of the supporting seats is 4, and the supporting plate is connected with the upper end of each supporting seat through a bolt.

Preferably, the sampling groove is fixed on the supporting seat.

Preferably, a drain valve is arranged at the bottom of the heat conduction shell, and the interior of the heat conduction shell can be regularly cleaned through the drain valve.

The utility model has the advantages that: the utility model discloses simple structure can improve the cooling effect of sample through the structure that changes the condenser pipe and the mode of arranging in the heat conduction shell, sets up radiating fin at heat conduction shell surface, can accelerate the heat exchange of cooling water and the outer air of heat conduction shell in the heat conduction shell, strengthens the radiating effect of cooling water, and the cooling effect of sample has further been strengthened in condenser pipe and radiating fin's combination, has consequently saved the cooling water consumption, the cost is reduced.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic top view of the condenser tube of the present invention;

shown in the figure:

1. the heat conduction shell, 2, inlet tube, 3, outlet pipe, 4, first stop valve, 5, condenser pipe, 6, advance appearance pipe, 7, play appearance pipe, 8, sample groove, 9, second stop valve, 10, third stop valve, 11, sample discharging pipe, 12, introduction port, 13, play appearance mouth, 14, radiating fin, 15, lid, 16, mounting panel, 17, supporting seat, 18, layer board, 19, blowoff valve.

Detailed Description

In order to clearly illustrate the technical features of the present solution, the present solution is explained below by way of specific embodiments.

As shown in fig. 1, the utility model comprises a support frame and a heat-conducting shell 1 arranged on the support frame, wherein the heat-conducting shell 1 is provided with a cooling water inlet and a cooling water outlet; the cooling water inlet is positioned at the lower part of the heat conduction shell 1, and the cooling water outlet is positioned at the upper part of the heat conduction shell 1. The cooling water inlet is connected with the water inlet pipe 2, the cooling water outlet is connected with the water outlet pipe 3, and the first stop valve 4 is installed on the water inlet pipe 2.

As shown in fig. 1 and 2, a condensation pipe 5 is arranged in the heat-conducting shell 1, the condensation pipe 5 is a pipe body structure which is arranged along the inner wall of the heat-conducting shell 1 in a ring shape and is distributed in a wave shape, one end of the condensation pipe 5 is connected with a sample inlet pipe 6, the other end of the condensation pipe is connected with a sample outlet pipe 7, and a sampling groove 8 for receiving a sample is arranged below a sample outlet of the sample outlet pipe 7; the sample inlet pipe 6 is provided with a second stop valve 9, and the sample outlet pipe 7 is provided with a third stop valve 10. The bottom of the sampling groove 8 is connected with the sampling pipe 11, the sampling groove 8 can facilitate sampling detection, and the sample is discharged from the sampling groove 8 through the sampling pipe 11.

The condenser pipe 5 includes the body structure of two inside and outside settings, the one end of body structure is introduction port 12, and the other end is out appearance mouth 13, and the introduction port 12 of two body structures all is connected with introduction pipe 6, and the play appearance mouth 13 of two body structures all is connected with a appearance pipe 7. The sample divides two tunnel cooling, can strengthen its cooling effect, require under certain prerequisite at sample flow promptly, the sample divides two tunnel to walk, can control its velocity of flow and slow down, consequently can increase the heat transfer time of sample and cooling water to improve the heat transfer effect of sample and cooling water, such structure of condenser pipe 5 can make it set up along 1 inner walls of heat conduction casing in addition, therefore the transmission that a part of heat of sample can be quick to external environment, reinforcing sample cooling effect. The outer surface of the heat conduction shell 1 is provided with heat dissipation fins 14, and the heat dissipation fins 14 are metal flowering fins. The heat radiating fins 14 can accelerate heat exchange between cooling water in the heat conducting shell 1 and air outside the heat conducting shell 1, enhance the heat radiating effect of the cooling water, facilitate cooling and save cooling water consumption. Because no cooling fin is additionally arranged on the surface of the condensation pipe 5, the surface is smooth, dirt is not easy to deposit and hang, the cleaning is convenient, and the heat dissipation effect of the condensation pipe 5 is ensured.

The heat conduction shell body 15 is installed to heat conduction shell body 1 upper end, and round mounting panel 16 is installed to the upper end of heat conduction shell body 1, mounting panel 16 and lid 15 bolted connection. The sample inlet pipe 6 and the sample outlet pipe 7 both penetrate through the cover body 15 to be connected with the condensation pipe 5. When the condensation pipe 5 is cleaned, the condensation pipe 5 is directly taken out together with the cover body 15 for cleaning, and the cleaning is very convenient.

The upper end of the condensation pipe 5 is located at the upper part of the heat conduction shell 1, and the lower end of the condensation pipe 5 is located at the bottom of the heat conduction shell 1. This increases the length of the condensation duct 5 as much as possible to improve the cooling effect of the sample.

The support frame includes supporting seat 17 and installs at supporting seat 17 upper bracket 18, layer board 18 and heat conduction casing 1 fixed connection specifically are the welding. In this embodiment, the number of the supporting seats 17 is 4, and the supporting plate 18 is connected to the upper end of each supporting seat 17 by bolts. The sampling groove 8 is fixed on a supporting seat 17.

A drain valve 19 is arranged at the bottom of the heat conduction shell 1, and the interior of the heat conduction shell 1 can be regularly cleaned through the drain valve 19.

During the specific use, open first stop valve 4, second stop valve 9 and third stop valve 10, the sample gets into condenser pipe 5 through advancing appearance pipe 6, the cooling water passes through inlet tube 2 and gets into in the heat conduction casing 1, flow out through outlet pipe 3, the cooling water in the heat conduction casing 1 carries out the heat exchange with the sample in the condenser pipe 5, and strengthen the radiating effect through radiating fin 14 on the heat conduction casing 1, the sample after the cooling flows into sample groove 8 through play appearance pipe 7, after the sample survey, the sample in sample groove 8 is through arranging appearance pipe 11 discharges.

The utility model discloses simple structure, through the structure that changes condenser pipe 5 and the cooling effect that the mode of arranging in heat conduction casing 1 can improve the sample, set up radiating fin 14 at 1 surface of heat conduction casing, can accelerate the heat exchange of 1 interior cooling water of heat conduction casing and 1 outer air of heat conduction casing, the radiating effect of reinforcing cooling water, condenser pipe 5 and radiating fin 14's combination has further strengthened the cooling effect of sample, consequently saved the cooling water consumption, the cost is reduced.

Of course, the above description is not limited to the above examples, and technical features of the present invention that are not described in the present application may be implemented by or using the prior art, and are not described herein again; the above embodiments and drawings are only used for illustrating the technical solutions of the present invention and are not intended to limit the present invention, and the present invention has been described in detail with reference to the preferred embodiments, and those skilled in the art should understand that changes, modifications, additions or substitutions made by those skilled in the art within the spirit of the present invention should also belong to the protection scope of the claims of the present invention.

Claims (8)

1. An efficient sampling cooler, characterized in that: the device comprises a support frame and a heat conduction shell (1) arranged on the support frame, wherein a cooling water inlet and a cooling water outlet are arranged on the heat conduction shell (1); a condensation pipe (5) is arranged in the heat conduction shell (1), the condensation pipe (5) is of a pipe body structure which is arranged along the inner wall of the heat conduction shell (1) in a ring mode and is distributed in a wave mode, one end of the condensation pipe (5) is connected with a sample inlet pipe (6), the other end of the condensation pipe is connected with a sample outlet pipe (7), and a sampling groove (8) for receiving a sample is arranged below a sample outlet of the sample outlet pipe (7); and heat radiating fins (14) are arranged on the outer surface of the heat conducting shell (1).

2. A high efficiency sampling cooler in accordance with claim 1, wherein: condenser pipe (5) include two inside and outside body structures that set up, the one end of body structure is introduction port (12), and the other end is out appearance mouth (13), and introduction port (12) of two body structures all are connected with introduction pipe (6), and the play appearance mouth (13) of two body structures all are connected with out appearance pipe (7).

3. A high efficiency sampling cooler according to claim 1 or claim 2, wherein: a second stop valve (9) is mounted on the sample inlet pipe (6), and a third stop valve (10) is mounted on the sample outlet pipe (7).

4. A high efficiency sampling cooler in accordance with claim 1, wherein: the bottom of the sampling groove (8) is connected with a sampling pipe (11).

5. A high efficiency sampling cooler in accordance with claim 1, wherein: the cooling water inlet is connected with the water inlet pipe (2), the cooling water outlet is connected with the water outlet pipe (3), and the first stop valve (4) is installed on the water inlet pipe (2).

6. A high efficiency sampling cooler in accordance with claim 1, wherein: the heat conduction shell is characterized in that a cover body (15) is installed at the upper end of the heat conduction shell (1), a circle of installation plate (16) is installed at the upper end of the heat conduction shell (1), and the installation plate (16) is connected with the cover body (15) through bolts.

7. A high efficiency sampling cooler in accordance with claim 1, wherein: the upper end of the condensation pipe (5) is positioned at the upper part of the heat conduction shell (1), and the lower end of the condensation pipe (5) is positioned at the bottom of the heat conduction shell (1).

8. A high efficiency sampling cooler in accordance with claim 1, wherein: the support frame comprises a support seat (17) and a supporting plate (18) arranged on the support seat (17), and the supporting plate (18) is fixedly connected with the heat conduction shell (1).

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