CN215765837U - Refrigerating system with evaporative condenser - Google Patents

Abstract

The utility model discloses a refrigeration system with an evaporative condenser, which comprises an ammonia compressor, the evaporative condenser fixedly connected with the air outlet of the ammonia compressor through a first connecting pipe, a first storage tank fixedly connected with the liquid outlet of the evaporative condenser through a second connecting pipe, a second storage tank fixedly connected with the liquid outlet of the first storage tank through a third connecting pipe, the air outlet of the first storage tank is fixedly connected with the first connecting pipe through a fourth connecting pipe, the evaporative condenser comprises an evaporative condenser body, the supporting mechanism is connected with the connecting plate through the adjusting mechanism, the supporting mechanism is convenient for adjusting the contact area of the evaporative condenser body and the ground, the stability of the evaporative condenser body in use is improved, and the adjusting mechanism is convenient for adjusting the bottom of the evaporative condenser body to be in a horizontal state.

Description

Refrigerating system with evaporative condenser

Technical Field

The utility model relates to the technical field of refrigeration equipment, in particular to a refrigeration system with an evaporative condenser.

Background

With the development of society, refrigerating system also applies more and more fields, and refrigerating system's theory of operation is: the compressor compresses a normal-temperature normal-pressure gaseous medium into a high-temperature high-pressure gaseous medium, the high-temperature high-pressure gaseous medium enters the condenser to be radiated to form a low-temperature high-pressure liquid medium, and the low-temperature high-pressure liquid medium is stored for refrigeration; the evaporative condenser in the existing refrigeration system is usually directly placed on the ground when being installed, and the ground is often inclined and uneven, so that the evaporative condenser is not stably placed and is easy to incline and shake, the normal use of the evaporative condenser is influenced, and in addition, the contact area between the bottom of the evaporative condenser and the ground is small and fixed, and the stability of the evaporative condenser is not facilitated.

Therefore, it is a problem to provide a refrigeration system with an evaporative condenser, which has a large contact area between the evaporative condenser and the ground and is stable in contact with the ground.

Disclosure of Invention

The utility model aims to provide a refrigerating system with an evaporative condenser, which has a large contact area between the evaporative condenser and the ground and is stable in contact.

The purpose of the utility model is realized as follows:

a refrigeration system with an evaporative condenser comprises an ammonia compressor, the evaporative condenser fixedly connected with an air outlet of the ammonia compressor through a first connecting pipe, a first storage tank fixedly connected with a liquid outlet of the evaporative condenser through a second connecting pipe, and a second storage tank fixedly connected with a liquid outlet of the first storage tank through a third connecting pipe, wherein an air outlet of the first storage tank is fixedly connected with the first connecting pipe through a fourth connecting pipe, the evaporative condenser comprises an evaporative condenser body, a connecting plate fixedly connected with the bottom of the evaporative condenser body, a plurality of adjusting mechanisms fixedly connected with the lower surface of the connecting plate, and a supporting mechanism fixedly connected with the bottom of the adjusting mechanisms.

The first storage tank is an ammonia storage tank.

The evaporative condenser is provided with at least two evaporative condensers which are connected in parallel through a pipeline.

The supporting mechanism comprises a supporting plate located in the horizontal direction and two plate adjusting mechanisms located on the lower surface of the supporting plate and enabling the length of the supporting plate to change, and the two plate adjusting mechanisms are located on the left side and the right side of the supporting plate.

The plate adjusting mechanism comprises a sliding groove, a sliding plate, a fixing body and a limiting mechanism, wherein the sliding groove is located on the lower surface of the supporting plate, the opening of the sliding groove is downward, the sliding plate is matched with the sliding groove, the fixing body is used for fixing the sliding plate and the sliding groove, the limiting mechanism is used for enabling the sliding plate to move along the length direction of the sliding groove, and the lower surface of the sliding plate and the lower surface of the supporting plate are on the same plane.

The adjusting mechanism comprises a first screw rod fixedly connected with the lower surface of the connecting plate, a sleeve sleeved at the bottom of the first screw rod and in threaded connection with the bottom of the first screw rod, and a second screw rod fixedly connected with the upper surface of the supporting plate at the bottom and in threaded connection with the sleeve at the top, and the direction of first threads of the first screw rod is opposite to the direction of second threads of the second screw rod.

The fixing body comprises a first fixing hole positioned on the supporting plate, a plurality of second fixing holes positioned on the sliding plate, and a screw rod in threaded connection with the first fixing hole and the second fixing holes.

The limiting mechanism comprises limiting grooves which are arranged on the front side surface and the rear side surface of the sliding groove and are arranged along the length direction of the sliding groove, and limiting blocks which are arranged on the front side surface and the rear side surface of the sliding plate and are matched with the limiting grooves.

Has the positive and beneficial effects that: the supporting mechanism is connected with the connecting plate through the adjusting mechanism, the supporting mechanism is convenient for adjusting the contact area of the evaporative condenser body and the ground, the stability of the evaporative condenser body in use is improved, the adjusting mechanism is convenient for adjusting the bottom of the evaporative condenser body to be in a horizontal state, and the stability of the evaporative condenser body in installation is ensured.

Drawings

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

FIG. 2 is a schematic structural view of an evaporator body according to the present invention;

FIG. 3 is a schematic view of the structure in the direction A-A;

FIG. 4 is a schematic view of the adjusting mechanism of the present invention;

in the figure, the following steps are carried out: the ammonia storage device comprises an ammonia compressor 1, an evaporative condenser 2, a first storage tank 3, a second storage tank 4, a first connecting pipe 5, a second connecting pipe 6, a third connecting pipe 7, a fourth connecting pipe 8, an evaporative condenser body 9, a connecting plate 10, a supporting plate 11, an adjusting mechanism 12, a sliding plate 13, a fixing screw 14, a sliding groove 15, a first fixing hole 16, a second fixing hole 17, a screw rod 18, a limiting mechanism 19, a limiting groove 20, a limiting block 21, a first screw rod 22, a second screw rod 23 and a sleeve 24.

Detailed Description

The utility model is further illustrated by the following figures and examples.

Example 1

As shown in fig. 1 and 2, a refrigeration system with an evaporative condenser comprises an ammonia compressor 1, an evaporative condenser 2 fixedly connected with an air outlet of the ammonia compressor 1 through a first connecting pipe 5, a first storage tank 3 fixedly connected with a liquid outlet of the evaporative condenser 2 through a second connecting pipe 6, and a second storage tank 4 fixedly connected with a liquid outlet of the first storage tank 3 through a third connecting pipe 7, wherein an air outlet of the first storage tank 3 is fixedly connected with the first connecting pipe 5 through a fourth connecting pipe 8, and the first storage tank 3 is an ammonia storage device. The evaporative condenser 2 is provided with at least two evaporative condensers 2, the at least two evaporative condensers 2 are connected in parallel through a pipeline, the ammonia compressor 1 compresses ammonia gas at normal temperature and normal pressure into high-temperature and high-pressure ammonia pressure, the high-temperature and high-pressure ammonia pressure enters the condensers to be radiated to form low-temperature and high-pressure liquid ammonia, the low-temperature and high-pressure liquid ammonia is stored for refrigeration, and the evaporative condenser 2 comprises an evaporative condenser body 9, a connecting plate 10 fixedly connected with the bottom of the evaporative condenser body 9, a plurality of adjusting mechanisms 12 fixedly connected with the lower surface of the connecting plate 10, and a supporting mechanism fixedly connected with the bottoms of the adjusting mechanisms 12. The supporting mechanism is connected with the connecting plate 10 through the adjusting mechanism 12, the supporting mechanism is convenient for adjusting the contact area of the evaporative condenser body 9 and the ground, the stability of the evaporative condenser body 9 in use is improved, the adjusting mechanism is convenient for adjusting the bottom of the evaporative condenser body 9 to be in a horizontal state, and the stability of the evaporative condenser body 9 in installation is guaranteed.

As shown in fig. 3, the supporting mechanism includes a supporting plate 11 located in the horizontal direction, and two plate adjusting mechanisms located on the lower surface of the supporting plate 11 and used for changing the length of the supporting plate 11, and the two plate adjusting mechanisms are located on the left and right sides of the supporting plate 11, so as to increase the contact area between the supporting plate 11 and the ground, thereby making the evaporative condenser body 1 stable during installation and improving the stability of the evaporative condenser body 9 during use. The plate adjusting mechanism comprises a sliding groove 15 which is positioned on the lower surface of the supporting plate 11 and has a downward opening, a sliding plate 13 which is matched with the sliding groove 15, a fixing body which is used for fixing the sliding plate 13 and the sliding groove 15, and a limiting mechanism 19 which is used for enabling the sliding plate 13 to move along the length direction of the sliding groove 15, the lower surface of the sliding plate 13 and the lower surface of the supporting plate 11 are on the same plane, so that the sliding plate 13 and the supporting plate 11 are both in contact with the ground conveniently, and therefore the evaporative condenser body 9 is in stable contact with the ground, the fixing body comprises a first fixing hole 16 which is positioned on the supporting plate 11, a plurality of second fixing holes 17 which are positioned on the sliding plate 13, and a screw 18 which is in threaded connection with the first fixing hole 16 and the second fixing holes 17, the sliding plate 13 is pulled to move leftwards along the length direction of the sliding groove 15, and when the sliding plate 13 is pulled to a set length, the first fixing hole 16 is aligned with the second fixing holes 17, the screw 18 is screwed into the first fixing hole 16 and the second fixing hole 17 and the slide plate 13 is fixed with the support plate 11.

As shown in fig. 4, the adjusting mechanism 12 includes a first screw rod 22 fixedly connected to the lower surface of the connecting plate 10, a sleeve 24 sleeved on the bottom of the first screw rod 22 and in threaded connection with the bottom of the first screw rod 22, and a second screw rod 23 fixedly connected to the upper surface of the supporting plate 11 and in threaded connection with the sleeve 24 at the top, wherein the direction of the first thread of the first screw rod 22 is opposite to the direction of the second thread of the second screw rod 23, when the bottom of the evaporative condenser body 9 needs to be adjusted, the sleeve 24 is rotated while the supporting plate 11 is ensured not to be rotated, and since the direction of the first thread of the first screw rod 22 is opposite to the direction of the second thread of the second screw rod 23, the end of the first screw rod 22 and the end of the second screw rod 23 are far away from or close to each other, thereby completing the leveling of the evaporative condenser body 1, the operation is simple, and the installation stability of the evaporative condenser body is ensured, the service life of the evaporative condenser is prolonged.

Example 2

As shown in fig. 1 and 2, a refrigeration system with an evaporative condenser comprises an ammonia compressor 1, an evaporative condenser 2 fixedly connected with an air outlet of the ammonia compressor 1 through a first connecting pipe 5, a first storage tank 3 fixedly connected with a liquid outlet of the evaporative condenser 2 through a second connecting pipe 6, and a second storage tank 4 fixedly connected with a liquid outlet of the first storage tank 3 through a third connecting pipe 7, wherein an air outlet of the first storage tank 3 is fixedly connected with the first connecting pipe 5 through a fourth connecting pipe 8, and the first storage tank 3 is an ammonia storage device. The evaporative condenser 2 is provided with at least two evaporative condensers 2, the at least two evaporative condensers 2 are connected in parallel through a pipeline, the ammonia compressor 1 compresses ammonia gas at normal temperature and normal pressure into high-temperature and high-pressure ammonia pressure, the high-temperature and high-pressure ammonia pressure enters the condensers to be radiated to form low-temperature and high-pressure liquid ammonia, the low-temperature and high-pressure liquid ammonia is stored for refrigeration, and the evaporative condenser 2 comprises an evaporative condenser body 9, a connecting plate 10 fixedly connected with the bottom of the evaporative condenser body 9, a plurality of adjusting mechanisms 12 fixedly connected with the lower surface of the connecting plate 10, and a supporting mechanism fixedly connected with the bottoms of the adjusting mechanisms 12. The supporting mechanism is connected with the connecting plate 10 through the adjusting mechanism 12, the supporting mechanism is convenient for adjusting the contact area of the evaporative condenser body 9 and the ground, the stability of the evaporative condenser body 9 in use is improved, the adjusting mechanism is convenient for adjusting the bottom of the evaporative condenser body 9 to be in a horizontal state, and the stability of the evaporative condenser body 9 in installation is guaranteed.

As shown in fig. 3, the supporting mechanism includes a supporting plate 11 located in the horizontal direction, and two plate adjusting mechanisms located on the lower surface of the supporting plate 11 and used for changing the length of the supporting plate 11, and the two plate adjusting mechanisms are located on the left and right sides of the supporting plate 11, so as to increase the contact area between the supporting plate 11 and the ground, thereby making the evaporative condenser body 1 stable during installation and improving the stability of the evaporative condenser body 9 during use. The plate adjusting mechanism comprises a sliding groove 15 which is positioned on the lower surface of the supporting plate 11 and has a downward opening, a sliding plate 13 which is matched with the sliding groove 15, a fixing body which is used for fixing the sliding plate 13 and the sliding groove 15, and a limiting mechanism 19 which is used for enabling the sliding plate 13 to move along the length direction of the sliding groove 15, the lower surface of the sliding plate 13 and the lower surface of the supporting plate 11 are on the same plane, so that the sliding plate 13 and the supporting plate 11 are both in contact with the ground conveniently, and therefore the evaporative condenser body 9 is in stable contact with the ground, the fixing body comprises a first fixing hole 16 which is positioned on the supporting plate 11, a plurality of second fixing holes 17 which are positioned on the sliding plate 13, and a screw 18 which is in threaded connection with the first fixing hole 16 and the second fixing holes 17, the sliding plate 13 is pulled to move leftwards along the length direction of the sliding groove 15, and when the sliding plate 13 is pulled to a set length, the first fixing hole 16 is aligned with the second fixing holes 17, the screw 18 is screwed into the first fixing hole 16 and the second fixing hole 17 and the slide plate 13 is fixed with the support plate 11.

As shown in fig. 4, the adjusting mechanism 12 includes a first screw rod 22 fixedly connected to the lower surface of the connecting plate 10, a sleeve 24 sleeved on the bottom of the first screw rod 22 and in threaded connection with the bottom of the first screw rod 22, and a second screw rod 23 fixedly connected to the upper surface of the supporting plate 11 and in threaded connection with the sleeve 24 at the top, wherein the direction of the first thread of the first screw rod 22 is opposite to the direction of the second thread of the second screw rod 23, when the bottom of the evaporative condenser body 9 needs to be adjusted, the sleeve 24 is rotated while the supporting plate 11 is ensured not to be rotated, and since the direction of the first thread of the first screw rod 22 is opposite to the direction of the second thread of the second screw rod 23, the end of the first screw rod 22 and the end of the second screw rod 23 are far away from or close to each other, thereby completing the leveling of the evaporative condenser body 1, the operation is simple, and the installation stability of the evaporative condenser body is ensured, the service life of the evaporative condenser is prolonged.

The limiting mechanism 19 comprises limiting grooves 20 which are located on the front side surface and the rear side surface of the sliding groove 15 and are arranged along the length direction of the sliding groove 15, and limiting blocks 21 which are located on the front side surface and the rear side surface of the sliding plate 13 and are matched with the limiting grooves 20, the limiting mechanism 19 is arranged to facilitate the sliding plate 13 to move along the length direction of the sliding groove 15, the sliding plate 13 is located in the sliding groove 15, and the bottom of the sliding plate 13 and the bottom of the supporting plate 11 are located on the same plane.

The supporting mechanism is connected with the connecting plate through the adjusting mechanism, the supporting mechanism is convenient for adjusting the contact area of the evaporative condenser body and the ground, the stability of the evaporative condenser body in use is improved, the adjusting mechanism is convenient for adjusting the bottom of the evaporative condenser body to be in a horizontal state, and the stability of the evaporative condenser body in installation is ensured.

Claims (8)

1. A refrigeration system with an evaporative condenser comprising an ammonia compressor, characterized in that: the ammonia compressor further comprises an evaporative condenser fixedly connected with the gas outlet of the ammonia compressor through a first connecting pipe, a first storage tank fixedly connected with the liquid outlet of the evaporative condenser through a second connecting pipe, and a second storage tank fixedly connected with the liquid outlet of the first storage tank through a third connecting pipe, wherein the gas outlet of the first storage tank is fixedly connected with the first connecting pipe through a fourth connecting pipe, and the evaporative condenser comprises an evaporative condenser body, a connecting plate fixedly connected with the bottom of the evaporative condenser body, a plurality of adjusting mechanisms fixedly connected with the lower surface of the connecting plate, and a supporting mechanism fixedly connected with the bottom of the adjusting mechanisms.

2. The refrigeration system with evaporative condenser, as recited in claim 1, wherein: the first storage tank is an ammonia storage tank.

3. The refrigeration system with evaporative condenser, as recited in claim 1, wherein: the evaporative condenser is provided with at least two evaporative condensers which are connected in parallel through a pipeline.

4. The refrigeration system with evaporative condenser, as recited in claim 1, wherein: the supporting mechanism comprises a supporting plate located in the horizontal direction and two plate adjusting mechanisms located on the lower surface of the supporting plate and enabling the length of the supporting plate to change, and the two plate adjusting mechanisms are located on the left side and the right side of the supporting plate.

5. The refrigeration system with an evaporative condenser, as recited in claim 4, wherein: the plate adjusting mechanism comprises a sliding groove, a sliding plate, a fixing body and a limiting mechanism, wherein the sliding groove is located on the lower surface of the supporting plate, the opening of the sliding groove is downward, the sliding plate is matched with the sliding groove, the fixing body is used for fixing the sliding plate and the sliding groove, the limiting mechanism is used for enabling the sliding plate to move along the length direction of the sliding groove, and the lower surface of the sliding plate and the lower surface of the supporting plate are on the same plane.

6. The refrigeration system with an evaporative condenser, as recited in claim 4, wherein: the adjusting mechanism comprises a first screw rod fixedly connected with the lower surface of the connecting plate, a sleeve sleeved at the bottom of the first screw rod and in threaded connection with the bottom of the first screw rod, and a second screw rod fixedly connected with the upper surface of the supporting plate at the bottom and in threaded connection with the sleeve at the top, and the direction of first threads of the first screw rod is opposite to the direction of second threads of the second screw rod.

7. The refrigeration system with an evaporative condenser, as recited in claim 5, wherein: the fixing body comprises a first fixing hole positioned on the supporting plate, a plurality of second fixing holes positioned on the sliding plate, and a screw rod in threaded connection with the first fixing hole and the second fixing holes.

8. The refrigeration system with an evaporative condenser, as recited in claim 5, wherein: the limiting mechanism comprises limiting grooves which are arranged on the front side surface and the rear side surface of the sliding groove and are arranged along the length direction of the sliding groove, and limiting blocks which are arranged on the front side surface and the rear side surface of the sliding plate and are matched with the limiting grooves.

Images