CN216023241U - Steam condensate water sampling device - Google Patents

Abstract

The utility model relates to the technical field of steam condensate water sampling, and discloses a steam condensate water sampling device, which comprises a cooling box, a water storage box and a water storage box, wherein the cooling box is used for storing cooling water; the cooling box includes: the cooling tank water injection port is formed in the top of the cooling tank; the cooling tank water inlet is formed in the cooling tank; the water outlet of the cooling box is formed in the cooling box; according to the steam condensate water sampling device provided by the utility model, the outside of the water condensation coil pipe in the cooling box is fully contacted, so that the efficient cooling of the steam in the condensation coil pipe is realized, meanwhile, the fin condenser cools the water in the cooling box, and the water pump controls the water circulation in the cooling box and the fin condenser, so that the condensation effect of the steam in the condensation coil pipe is further accelerated, and the sampling efficiency of the steam condensate water is improved.

Description

Steam condensate water sampling device

Technical Field

The utility model relates to the technical field of steam condensate water sampling, in particular to a steam condensate water sampling device.

Background

Pure steam is also called clean steam or high quality steam, and the condensed water of the pure steam meets the requirements of pharmacopoeia on water for injection. Pure steam is widely used for online sterilization operation of pharmaceutical equipment, and a pure steam system belongs to a direct influence system according to the requirement of ISPE system division.

Coil pipe direct contact solid state radiator that current steam sampling device adopted, the radiator material is aluminium or copper, and steam passes through the coil pipe, passes through the coil pipe with the heat and transmits to the radiator, and the rethread fan accelerates the heat and gives off, and steam cooling becomes the comdenstion water. Because the coil pipe direct contact heat dissipation solid of current steam sampling device, therefore hardly accomplish coil pipe and the solid inseparable laminating of heat dissipation, can produce the gap. The air in the gap can reduce the radiating efficiency of the coil pipe, and then the sampling efficiency of the steam condensate water is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problem of poor sampling efficiency of steam condensate water in the prior art, and provides a sampling device of the steam condensate water.

In order to achieve the above object, an aspect of the present invention provides a steam condensate sampling apparatus, including:

a cooling tank for storing cooling water; the cooling box includes:

the cooling tank water injection port is formed in the top of the cooling tank;

the cooling tank water inlet is formed in the cooling tank;

the water outlet of the cooling box is formed in the cooling box;

condensing coil, condensing coil sets up inside the cooler bin, include:

the condensation coil inlet is arranged at the top of the cooling box and is communicated with one end of the condensation coil;

the condensation coil outlet is arranged outside the cooling box and is communicated with the other end of the condensation coil;

one end of the water circulation module is communicated with the water inlet of the cooling box and is used for controlling the water in the cooling box to circularly flow;

one end of the cooling module is communicated with the other end of the water circulation module; the other end of the cooling module is communicated with the water outlet of the cooling box.

Preferably, the water circulation module includes:

a water pump, the water pump comprising:

the water outlet of the water pump is communicated with the water inlet of the cooling box;

and the water inlet of the water pump is communicated with one end of the cooling module.

Preferably, the cooling module comprises:

a finned condenser, comprising:

the fin condenser inlet is communicated with the cooling tank water outlet;

and the outlet of the fin condenser is communicated with the water inlet of the water pump.

Preferably, the cooling module further comprises a fan disposed above the finned condenser.

Preferably, the vertical height of the cooling box water inlet is lower than that of the cooling box water outlet.

Preferably, the cooling box water inlet is arranged at the bottom of the cooling box, and the cooling box water outlet is arranged on the side wall of the cooling box.

Preferably, a temperature sensor is fixedly mounted on the side wall of the outlet of the condensing coil.

Preferably, the condensing coil is welded inside the cooling tank.

Preferably, the water inlet of the cooling tank is communicated with the water outlet of the water pump through a water pipe; the water inlet of the water pump is communicated with the outlet of the fin condenser through a water pipe; and the inlet of the fin condenser is communicated with the water outlet of the cooling box through a water pipe.

According to the technical scheme, the steam condensate water sampling device provided by the utility model has the advantages that the outside of the water condensate coil inside the cooling box is fully contacted, the efficient cooling of the steam inside the condensate coil is realized, meanwhile, the fin condenser cools the water inside the cooling box, the water pump controls the water circulation in the cooling box and the fin condenser, the condensation effect of the steam inside the condensate coil is further accelerated, and the sampling efficiency of the steam condensate water is improved.

Drawings

Fig. 1 is a schematic structural view of a steam condensate sampling apparatus according to an embodiment of the present invention;

fig. 2 is a block diagram of a steam condensate sampling apparatus according to an embodiment of the present invention.

Description of the reference numerals

1. Condensing coil 2 and cooling box

3. Fin condenser 4 and water pump

5. Temperature sensor 6 and fan

11. Condenser coil inlet 12 and condenser coil outlet

21. Cooling box water outlet 22 and cooling box water inlet

23. Water filling port 31 of cooling tank and inlet of finned condenser

32. Outlet 41 of fin condenser and water inlet of water pump

42. Water pump water outlet 7 and water circulation module

8. Cooling module

Detailed Description

The following detailed description of embodiments of the utility model refers to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the present invention, are given by way of illustration and explanation only, not limitation.

Fig. 1 is a schematic structural view of a steam condensate water sampling apparatus according to an embodiment of the present invention. As shown in fig. 1, the sampling device may include a condensing coil 1, a cooling tank 2, a water circulation module 7, and a temperature reduction module 8. Further, the condenser coil 1 may include a condenser coil inlet 11 and a condenser coil outlet 12. Further, the cooling tank 2 may include a cooling tank water inlet 22, a cooling tank water outlet 21, and a cooling tank water inlet 23.

The condensing coil 1 is welded inside the cooling box 2, and the condensing coil inlet 11 is arranged at the top of the cooling box 2 and is communicated with one end of the condensing coil 1; the outlet 12 of the condensing coil is arranged outside the cooling box 2 and is communicated with the other end of the condensing coil 1. The cooling tank water injection port 22 is opened at the top of the cooling tank 2. One end of the water circulation module 7 is communicated with the water inlet 21 of the cooling tank, and the other end of the water circulation module 7 is communicated with one end of the cooling module 8. The other end of the cooling module 8 is communicated with a water outlet 21 of the cooling box.

When the steam in the condensing coil 1 needs to be cooled, water is injected along the cooling tank water injection port 23, and then the steam is controlled to enter the condensing coil 1 along the condensing coil inlet 11. Steam absorbs heat for condensing coil 1 with heat transfer, and the water in cooler bin 2 absorbs the heat on condensing coil 1, and then makes steam can cool down along condensing coil 1 to condensate into water gradually in condensing coil 1. And simultaneously monitoring the temperature at the outlet 12 of the condensing coil, and controlling the water circulation module 7 to start when the temperature at the outlet 12 of the condensing coil is higher than the required temperature. Water circulation module 7 drives the water in cooler bin 2 and carries out the circulation flow, and the water in cooler bin 2 is owing to absorb the heat on condensing coil 1 and heat up gradually, and rivers to cooling module 8 after the control of water circulation module 7 intensifies the temperature, and the cooling module is cooled down to the water after the intensification. The water after the cooling flows to water circulation module 7 again to water after controlling the cooling through water circulation module 7 flows back to inside cooling tank 2 along cooling tank water inlet 22, and the hydroenergy after the cooling can absorb the heat on condensing coil 1 once more, and then can realize the steam cooling in condensing coil 1's steam cycle's purpose, has promoted the formation of steam condensate water. Among traditional steam condensate water sampling device, through condenser coil 1 and the realization of heat dissipation solid direct contact, because condenser coil 1 special shape, condenser coil 1 can't closely laminate with the heat dissipation solid, leads to producing many air gaps with the heat dissipation solid, consequently can restrict condenser coil 1's radiating efficiency. In this embodiment, since the steam condensate sampling device provided by the present invention uses water in direct contact with the condensing coil 1, the water can completely cover the outside of the condensing coil 1. And because the mobility of water, can accelerate the thermal flow on condensing coil 1, and then can high-efficiently cool condensing coil 1, improved the purpose of the inside steam condensation of condensing coil 1 greatly.

In the embodiment of the present invention, as for the specific structure of the water circulation module 7, various forms such as a water circulation machine, a water pump, etc. known to those skilled in the art may be adopted. In a preferred example of the present invention, however, the specific structure of the water circulation module 7 may be as shown in fig. 1 in consideration of the practicality and economy of the water circulation module 7. In the fig. 1, further, the water circulation module 7 may include a water pump 4. Further, the water pump 4 may include a water pump inlet 41 and a water pump outlet 42.

The water inlet 41 of the water pump is communicated with one end of the cooling module 8, and the water outlet 42 of the water pump is communicated with the water inlet 22 of the cooling tank.

When the water circulation flow in the cooling box 2 needs to be controlled, the water pump 4 is controlled to be started. Drive rivers to cooling module 8 after the inside intensification of cooler bin 2, after cooling module 8 is to the water cooling, pump into to water pump 4 inside along water pump water inlet 41 again. At the same time, the water pump 4 pumps the cooled water out along the water pump inlet 41 and finally returns to the interior of the cooling tank 2 along the cooling tank inlet 22. Make the inside water of cooler bin 2 constantly flow for the heat is constantly taken out by the transmission, and has guaranteed that the inside temperature of cooler bin 2 can cool off the steam in condenser coil 1. Drive the inside hydrologic cycle of cooler bin 2 through water pump 4 and flow, can accelerate thermal scattering and disappearing, the inside steam of condenser coil 1 can stablize the cooling, and then has improved the efficiency of steam condensation.

In the embodiment of the present invention, the specific structure of the cooling module 8 may be various types known to those skilled in the art, such as an air cooler, a water cooler, and the like. However, in a preferred example of the present invention, the specific structure of the cooling module 8 may be as shown in fig. 1 in consideration of the cooling effect and simplicity of the cooling module 8. In the fig. 1, the desuperheating module 8 may include a finned condenser 3 and a fan 6. Further, the fin condenser 3 may comprise a fin condenser inlet 31 and a fin condenser outlet 32.

The inlet 31 of the fin condenser is communicated with the water outlet 21 of the cooling tank, the outlet 32 of the fin condenser is communicated with the water inlet 41 of the water pump, and the fan 6 is arranged on one side of the fin condenser 3.

When water pump 4 control cooling tank 2 inside water circulation flows, the cooling tank 2 in the back along cooling tank delivery port 21 and fin condenser import 31 entering fin condenser 3 after the intensification, fin condenser 3 absorbs the heat of the aquatic after the intensification, the temperature of water reduces, realizes the preliminary cooling of water. Meanwhile, the fan 6 is controlled to be started, the flow of heat around the fin condenser 3 is accelerated, the heat dissipation of the fin condenser 3 is accelerated, and meanwhile the efficiency of transferring the heat to the fin condenser 3 by water is improved. And then improved the water cooling's after the intensification efficiency for the water in cooler bin 2 maintains the temperature that can make the steam condensation, has improved the stability and the effect of steam condensation greatly.

As shown in fig. 1, in the embodiment of the present invention, the sampling device may further include a temperature sensor 5 and a controller.

The temperature sensor 5 is fixedly arranged on the side wall of the outlet 12 of the condensing coil, and the temperature sensor 5 is connected with the controller.

After the high-temperature steam enters from the condensing coil inlet 11, the temperature sensor 5 monitors the temperature at the condensing coil outlet 12, and when the detected temperature is within the required temperature range, the water pump 4 and the fan 6 are controlled not to be started. When waiting for temperature sensor 5 to detect the unsatisfied temperature of requirement of temperature of condenser coil export 12 department, start water pump 4 and fan 6 simultaneously, the water pump drives the inside water of cooler bin 2 and carries out the circulation flow, and fan 6 cools down so that control the steam condensation better to water. The controller can adjust the operating power of the fan 6 in real time according to the temperature detected by the temperature sensor 5. The electric energy consumed when the fan 6 runs is reduced while the steam can be stably condensed into water. The sampling device can intelligently control the power of the fan 6, and the energy consumption is reduced.

In this embodiment of the present invention, the relative positions of the cooling box water outlet 21 and the cooling box water inlet 22 may be in various forms known to those skilled in the art, such as the cooling box water outlet 21 being at the same height as the cooling box water inlet 22, the cooling box water outlet 21 being at a smaller height than the cooling box water inlet 22, and the like. However, in a preferred embodiment of the present invention, the relative positions of the cooling tank water outlet 21 and the cooling tank water inlet 22 can be as shown in fig. 1, considering the cooling effect of the water flow direction on the steam inside the condensing coil 1. Specifically, the height of the cooling tank water inlet 22 is smaller than the cooling tank water outlet 21. Further, the cooling box water inlet 22 is formed at the bottom of the cooling box 2, and the cooling box water outlet 21 is formed at the side wall of the cooling box 2.

The vapor enters along the condensing coil inlet 11 and exits along the condensing coil outlet 12. During the steam cooling process, the water pump 4 controls the water to flow in along the cooling tank water inlet 22 and flow out along the cooling tank water outlet 21. The water flow direction is opposite to the steam flow direction, so that the heat exchange efficiency of the water and the condensing coil pipe 1 is increased, and the steam condensing efficiency is further improved.

In this embodiment of the utility model, the sampling device may also include a water tube, as shown in fig. 1.

The water inlet 22 of the cooling box is communicated with the water outlet 42 of the water pump through a water pipe; the water inlet 41 of the water pump is communicated with the outlet 32 of the fin condenser through a water pipe; the inlet 31 of the fin condenser is communicated with the water outlet 21 of the cooling tank through a water pipe.

The water pipe connects the cooling tank 2, the fin condenser 3, and the water pump 4 to form a water circulation circuit. The water circulation flow in the cooling box 2 is convenient to control, and the condensation effect on steam is improved.

Fig. 2 is a block diagram of a steam condensate sampling apparatus according to an embodiment of the present invention. As shown in fig. 2, when the steam inside the condensing coil 1 needs to be cooled, water is injected along the cooling tank water injection port 23, and then the steam is controlled to enter the condensing coil 1 along the condensing coil inlet 11. Steam absorbs heat for condensing coil 1 with heat transfer, and the water in cooler bin 2 absorbs the heat on condensing coil 1, and then makes steam can cool down along condensing coil 1 to condensate into water gradually in condensing coil 1. And simultaneously monitoring the temperature of the temperature sensor 5, and controlling the water pump 4 and the fan 6 to be started when the temperature of the cold temperature sensor 5 is higher than the required temperature. The water that heats up in the water pump 4 control cooling box 2 gets into condenser fin 3 along cooling box delivery port 21 and fin condenser import 31, and fin condenser 3 absorbs the heat of the aquatic after the intensification and gives off to the air in, and fan 6 accelerates the peripheral thermal flow of fin condenser 3, and then can carry out rapid cooling to water. The water after the cooling is pumped into by water pump 4 along fin condenser export 32 and water pump water inlet 41, and water pump 4 is with the water after the cooling is pumped into along water pump delivery port 42 and cooling box water inlet 22, and then realizes the circulative cooling's of water mesh. Make the steam among the condenser coil 1 can stabilize the condensation, improved the efficiency of steam condensation simultaneously, more convenient high efficiency.

According to the technical scheme, the steam condensate water sampling device provided by the utility model has the advantages that the outside of the water condensate coil inside the cooling box is fully contacted, the efficient cooling of the steam inside the condensate coil is realized, meanwhile, the fin condenser cools the water inside the cooling box, the water pump controls the water circulation in the cooling box and the fin condenser, the condensation effect of the steam inside the condensate coil is further accelerated, and the sampling efficiency of the steam condensate water is improved.

The preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, however, the present invention is not limited to the specific details of the above embodiments, and various simple modifications can be made to the technical solution of the present invention within the technical idea of the present invention, and these simple modifications are within the protective scope of the present invention. It should be noted that the various technical features described in the above embodiments can be combined in any suitable manner without contradiction, and the utility model is not described in any way for the possible combinations in order to avoid unnecessary repetition.

In addition, any combination of the various embodiments of the present invention is also possible, and the same should be considered as the disclosure of the present invention as long as it does not depart from the spirit of the present invention.

Claims (9)

1. A steam condensate water sampling apparatus, comprising:

a cooling tank (2) for storing cooling water; the cooling box (2) comprises:

the cooling tank water injection port (23) is formed in the top of the cooling tank (2);

the cooling tank water inlet (22), the cooling tank water inlet (22) is arranged on the cooling tank (2);

the cooling box water outlet (21), the cooling box water outlet (21) is arranged on the cooling box (2);

condensing coil (1), condensing coil (1) sets up inside cooler bin (2), include:

the condensation coil inlet (11) is arranged at the top of the cooling box (2), and is communicated with one end of the condensation coil (1);

the condensation coil outlet (12) is arranged outside the cooling box (2), and the condensation coil outlet (12) is communicated with the other end of the condensation coil (1);

one end of the water circulation module (7) is communicated with the cooling box water inlet (22) and is used for controlling the water circulation flow in the cooling box (2);

the cooling module (8), one end of the cooling module (8) is communicated with the other end of the water circulation module; the other end of the cooling module is communicated with a water outlet (21) of the cooling box.

2. The sampling device according to claim 1, characterized in that said water circulation module (7) comprises:

a water pump (4), the water pump (4) comprising:

the water pump water outlet (42), the said water pump water outlet (42) communicates with said cooling tank water inlet (22);

a water pump water inlet (41), the water pump water inlet (41) with the one end intercommunication of cooling module (8).

3. Sampling device according to claim 2, characterized in that said cooling module (8) comprises:

a finned condenser (3), the finned condenser (3) comprising:

a finned condenser inlet (31), the finned condenser inlet (31) being in communication with the cooling tank water outlet (21);

a finned condenser outlet (32), the finned condenser outlet (32) being in communication with the water pump water inlet (41).

4. A sampling device according to claim 3, characterized in that the cooling module (8) further comprises a fan (6), the fan (6) being arranged on the side of the finned condenser (3).

5. A sampling device according to claim 1, characterized in that the vertical height of the cooling box water inlet (22) is lower than the cooling box water outlet (21).

6. A sampling device according to claim 5, characterized in that the cooling box water inlet (22) opens at the bottom of the cooling box (2) and the cooling box water outlet (21) opens at the side wall of the cooling box (2).

7. A sampling device according to claim 1, characterized in that a temperature sensor (5) is fixedly mounted to the side wall of the condenser coil outlet (12).

8. Sampling device according to claim 1, characterized in that the condensation coil (1) is welded inside the cooling box (2).

9. A sampling device according to claim 3, characterized in that the cooling tank inlet (22) is in water-line communication with the pump outlet (42); the water inlet (41) of the water pump is communicated with the outlet (32) of the fin condenser through a water pipe; and the inlet (31) of the fin condenser is communicated with the water outlet (21) of the cooling box through a water pipe.

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