CN115682491A - Liquid level detection and adjustment device for ice making evaporation system - Google Patents

Abstract

The invention discloses a liquid level detection and adjustment device for an ice-making evaporation system, which comprises a water storage box, wherein a water pumping pipe for supplying water to an ice-making evaporator is arranged on the side wall of the water storage box, a water conveying pipe for supplying water to the inside of the water storage box is also arranged on the side wall of the water storage box, floating balls are fixedly arranged at the free ends of a first rotating arm and a second rotating arm, a sliding connection plate is connected to the upper side of an L-shaped frame in a sliding manner, and the L-shaped frame is controlled to rotate through a transmission part when moving transversely along with the first rotating arm. In the invention, when the liquid level in the water storage box is reduced to the low point of the water level, the strip-shaped frame moves to drive the knob to be unscrewed, and the water outlet head is controlled to automatically inject water; in the process that the liquid level rises in the water storage box, the strip-shaped frame control knob is gradually turned off, when the liquid level in the water storage box reaches the corresponding height, the water outlet head is completely closed, the detection and adjustment of liquid level conversion in the water storage box can be automatically realized through the change of the height of the floating ball, and the purposes of reducing the production, use and maintenance cost of the device are achieved.

Description

Liquid level detection and adjustment device for ice making evaporation system

Technical Field

The invention relates to the technical field of ice making evaporation systems, in particular to a liquid level detection and adjustment device for an ice making evaporation system.

Background

In recent years, the supercooled water type dynamic ice slurry preparation technology is widely applied to the fields of central air-conditioning cold accumulation, process cooling, agricultural product and fishery fresh-keeping and the like.

The common ice slurry conveying system adopts a flow state conveying mode, and water is directly pumped into the cooling unit through a pipeline, so that flow state ice water forms ice slurry. In-process that carries out the pump sending through the water pump to the water in the water tank, need detect the water level in the water tank, whether guarantee the water in the water tank and keep at safe water level, if the water level in the water tank is low excessively, lead to the unable effect of water pump, the phenomenon of pump body idle running can appear to lead to organism subassembly to break down easily. The existing measures adopted for solving the problem of low water level in the water tank are as follows: through setting up two liquid level detection appearance, carry out liquid level monitoring to the liquid level low point in the water tank and liquid level high point respectively, water when the water in the water tank is consumed to the low level, the liquid level detection appearance that is located the low point can send signal to the controller, control water pipe is to the inside water injection of water tank, water when being poured into to the high level in the water tank, the liquid level detection appearance that is located the high point will send signal to the controller, control water pipe stops the water injection operation, thereby realize the automated inspection adjustment to the water tank liquid level, this kind of adjustment mode needs arrange corresponding consumer and satisfy the function to liquid level detection in the evaporation system of making ice, increase ice making device's production input to a certain extent, and the maintenance cost when using in the equipment later stage, simultaneously because the addding of the consumer in the organism, need provide the heat dissipation of corresponding power for the operation of electrical equipment in the box, lead to the consumption that needs more energy in the operation of making ice.

Based on the defects, the liquid level detection and adjustment device for the ice-making evaporation system is provided.

Disclosure of Invention

The invention aims to: in order to solve the problems, the liquid level detection and adjustment device for the ice making evaporation system is provided.

In order to achieve the purpose, the invention adopts the following technical scheme: a liquid level detection and adjustment device for an ice-making evaporation system comprises a water storage box, wherein a water pumping pipe for supplying water to an ice-making evaporation machine is arranged on the side wall of the water storage box, a water delivery pipe for supplying water to the inside of the water storage box is also arranged on the side wall of the water storage box, a water outlet head corresponding to the water delivery pipe is arranged at the inner side end of the water storage box, a square frame is fixedly arranged at the opening end of the water storage box, and the upper end of the square frame is rotatably connected with a knob for controlling the opening and closing of the water outlet head;

the upper opening end of the water storage box is fixedly provided with a square frame, the interior of the water storage box is rotationally connected with two shaft levers which are symmetrically distributed, the outer ends of the two shaft levers are respectively and fixedly provided with two first spiral arms and two second spiral arms, notches which are matched with the second spiral arms to penetrate through are formed in the first spiral arms, and floating balls are fixedly arranged at the free ends of the first spiral arms and the second spiral arms;

the inner side of the water storage box is connected with an L-shaped frame corresponding to the first spiral arm and the second spiral arm in a sliding mode, the side ends of the first spiral arm and the second spiral arm are connected with sliding blocks in a rotating mode through rotating shafts, the sliding blocks are connected with the L-shaped frame in a sliding mode, the upper side of the L-shaped frame is connected with a sliding connection plate in a sliding mode, and a triangular groove for guiding the sliding connection plate to slide along the L-shaped frame is formed in the upper end face of the square frame;

the upper end of square frame sets firmly U type pallet, and goes out the water head and upwards run through U type pallet, the side of water head sets firmly the support arm, L type frame is when following first spiral arm lateral shifting, through the rotation of drive unit control knob.

Preferably, the inside of raceway rotates and is connected with the globe valve, the internally mounted of raceway has the closed O type circle of cooperation globe valve opening, the bottom of knob sets firmly the control globe valve pivoted valve rod.

Preferably, a support rod is fixedly arranged in the notch, and a strip-shaped groove matched with the support rod to slide is formed in the second swing arm.

Preferably, the bottom of the sliding connection plate is fixedly provided with a pin shaft, the outer side of the pin shaft is slidably sleeved with a sliding sleeve, and the outer side of the pin shaft is sleeved with a spring acting on the sliding sleeve downwards.

Preferably, the triangular groove is formed by communicating a first groove, a second groove and a third groove, the end face of the first groove is higher than the second groove, and the third groove is used for the transition of the sliding sleeve from the second groove to the first groove.

Preferably, transmission part includes the strip frame of sliding connection in U type pallet bottom to and the subassembly is pull to the gravity that control strip frame slides and resets.

Preferably, a convex block is fixedly arranged at the upper end of the sliding connection plate, a driven rod is fixedly arranged at the lower end of the support arm, and a strip-shaped rail matched with the convex block and the driven rod to slide is formed inside the strip-shaped frame.

Preferably, an arc-shaped groove matched with the driven rod to penetrate is formed in the U-shaped stand.

Preferably, the gravity traction assembly comprises a support table fixedly arranged at the bottom of the square frame through a stand column, a vertical rod is fixedly arranged at the upper end of the support table, a counterweight sleeve is slidably arranged on the outer side of the vertical rod in a sleeved mode, and a traction rope is bolted between the side end of the strip-shaped frame and the counterweight sleeve.

Preferably, a reversing wheel for changing the acting direction of the traction rope is arranged on the square frame.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

in the application, when the liquid level in the water storage box is lowered, the L-shaped frame moves along the horizontal direction along with the rotation of the first rotary arm and the second rotary arm until the floating ball is lowered to the low point of the water level, the counterweight sleeve drags the strip-shaped frame through the traction rope to drive the knob to be unscrewed, and the automatic water injection of the water outlet head is controlled; in the process that the liquid level rises in the water storage box, the strip-shaped frame control knob is gradually screwed off until the liquid level in the water storage box reaches the corresponding height, the water outlet head is completely closed, the detection and adjustment of liquid level conversion in the water storage box can be automatically realized through the change of the height of the floating ball, and a series of electronic monitoring components are replaced, so that the aims of reducing the production, use and maintenance cost of the device are fulfilled.

Drawings

Figure 1 shows an external perspective view of a reservoir box provided according to an embodiment of the invention;

fig. 2 shows an internal block diagram of a reservoir box provided in accordance with an embodiment of the invention;

figure 3 shows a front cross-sectional view of a reservoir box provided according to an embodiment of the invention;

fig. 4 is a top view of a bottom structure of a U-shaped stand according to an embodiment of the present invention;

FIG. 5 shows a cross-sectional side view of a reservoir box provided according to an embodiment of the invention;

fig. 6 shows an exploded view of a square frame top structure provided in accordance with an embodiment of the present invention.

Illustration of the drawings:

1. a water storage box; 2. a shaft lever; 3. a first swing arm; 301. a recess; 4. a second swing arm; 401. a strip-shaped groove; 5. a strut; 6. a floating ball; 7. an L-shaped frame; 8. a slider; 9. a sliding connection plate; 10. a bump; 11. a pin shaft; 12. a spring; 13. a sliding sleeve; 14. a square frame; 1401. a first groove; 1402. a second groove; 1403. a third groove; 15. a strip-shaped frame; 1501. a strip track; 16. supporting a platform; 17. a vertical rod; 18. a counterweight sleeve; 19. a reversing wheel; 20. a hauling rope; 21. a U-shaped stand; 2101. an arc-shaped slot; 22. a knob; 23. a support arm; 24. a driven lever; 25. a valve stem; 26. a ball valve; 27. a water delivery pipe; 28. an O-shaped ring; 29. a water outlet head; 30. a water pumping pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution: a liquid level detection and adjustment device for an ice-making evaporation system comprises a water storage box 1, wherein a water pumping pipe 30 for supplying water to an ice-making evaporation machine is arranged on the side wall of the water storage box 1, a water delivery pipe 27 for supplying water to the inside of the water storage box 1 is also arranged on the side wall of the water storage box 1, a water outlet head 29 corresponding to the water delivery pipe 27 is arranged at the inner side end of the water storage box 1, a square frame 14 is fixedly arranged at the opening end of the water storage box 1, and a knob 22 for controlling the opening and closing of the water outlet head 29 is rotatably connected to the upper end of the square frame 14; the water storage box 1 is arranged in an ice maker, water in the water storage box 1 is sent into the ice making evaporator through a water suction pump arranged in the ice maker, and when the water level in the water storage box 1 is lowered to a corresponding height, a water delivery pipe 27 connected with a water pipe is enabled to inject water into the water storage box 1 through a water outlet head 29 by rotating a knob 22.

The upper opening end of the water storage box 1 is fixedly provided with a square frame 14, the interior of the water storage box 1 is rotatably connected with two shaft levers 2 which are symmetrically distributed, the outer ends of the two shaft levers 2 are respectively and fixedly provided with two first swing arms 3 and two second swing arms 4, notches 301 which are matched with the second swing arms 4 to penetrate through are formed in the first swing arms 3, and the free ends of the first swing arms 3 and the second swing arms 4 are fixedly provided with floating balls 6; along with the rising of the water level, the first radial arm 3 and the second radial arm 4 rotate upwards under the action of the buoyancy of the floating ball 6, and along with the falling of the water level, the first radial arm 3 and the second radial arm 4 rotate downwards under the action of the buoyancy of the floating ball 6; through the arrangement of the notch 301, the first radial arm 3 and the second radial arm 4 are distributed in a crossed manner, and when acted by the floating ball 6, the first radial arm 3 and the second radial arm 4 which are distributed oppositely simultaneously act on the L-shaped frames 7 distributed at the same side.

The inner side of the water storage box 1 is connected with an L-shaped frame 7 corresponding to the first spiral arm 3 and the second spiral arm 4 in a sliding mode, the side ends of the first spiral arm 3 and the second spiral arm 4 are connected with a sliding block 8 in a rotating mode through a rotating shaft, the sliding block 8 is connected with the L-shaped frame 7 in a sliding mode, the upper side of the L-shaped frame 7 is connected with a sliding connection plate 9 in a sliding mode, and a triangular groove for guiding the sliding connection plate 9 to slide along the L-shaped frame 7 is formed in the upper end face of the square frame 14; when the first radial arm 3 and the second radial arm 4 move along with the floating ball 6, the first radial arm and the second radial arm act on the L-shaped frame 7 through the sliding block 8, so that the L-shaped frame 7 moves along the horizontal direction, and a vertical groove matched with the sliding block 8 to slide and a transverse groove matched with the sliding connection plate 9 to slide are formed in the L-shaped frame 7; when the sliding block 8 drives the L-shaped frame 7 to move horizontally, the sliding block 8 slides along the vertical groove.

The upper end of the square frame 14 is fixedly provided with a U-shaped stand 21, a water outlet head 29 upwards penetrates through the U-shaped stand 21, the side end of the water outlet head 29 is fixedly provided with a support arm 23, and the L-shaped stand 7 is controlled to rotate by a transmission part control knob 22 when moving transversely along with the first rotary arm 3; when the water outlet head 29 injects water into the water storage box 1, the height of the floating ball 6 is raised, and the rotary arm is driven to be raised upwards, at this time, the L-shaped frame 7 is close to the water outlet head 29 along the horizontal direction, in the process, the transmission part drives the knob 22 to rotate through the support arm 23 until the liquid level in the water storage box 1 rises to the corresponding height, the closing of the water outlet head 29 is completed, and at this time, the water outlet head 29 stops injecting water into the water storage box 1.

Specifically, as shown in fig. 3, a ball valve 26 is rotatably connected inside the water pipe 27, an O-ring 28 that is matched with the ball valve 26 and has a closed opening is installed inside the water pipe 27, and a valve rod 25 that controls the ball valve 26 to rotate is fixedly arranged at the bottom of the knob 22; the opening of the ball valve 26 is staggered with the O-shaped ring 28 by rotating the control knob 22, so that the water pipe 27 is cut off, and the water outlet of the water outlet head 29 is limited; along with the rotation of the ball valve 26, the water injection flow of the water outlet head 29 is gradually reduced, when the floating ball 6 reaches a predetermined height, the water outlet head 29 is completely closed, the water storage box 1 stops injecting water continuously, and the water flow of the water outlet head 29 is gradually reduced by controlling, so that after the floating ball 6 rises to a corresponding height, the water outlet head 29 can stop water supply operation in time in a trickle water outlet mode, and accurate control of the water injection amount is facilitated.

Specifically, as shown in fig. 2-6, a supporting rod 5 is fixedly arranged in the notch 301, a strip-shaped groove 401 matched with the supporting rod 5 to slide is formed in the second swing arm 4, when the first swing arm 3 and the second swing arm 4 move along with the floating ball 6, the supporting rod 5 fixed in the notch 301 slides along the strip-shaped groove 401, so that the first swing arm 3 and the second swing arm 4 which are distributed in a staggered manner are always kept at the same height without being influenced by the fluctuation of the liquid level in the water storage box 1, the stable transmission of the first swing arm 3 and the second swing arm 4 to the L-shaped frame 7 is realized, and the opening and closing of the water outlet head 29 are favorably controlled.

Specifically, as shown in fig. 4-6, a pin 11 is fixedly arranged at the bottom of the sliding plate 9, a sliding sleeve 13 is slidably sleeved outside the pin 11, and a spring 12 acting on the sliding sleeve 13 downwards is sleeved outside the pin 11; the triangular groove is formed by communicating a first groove 1401, a second groove 1402 and a third groove 1403, wherein the end face of the first groove 1401 is higher than the second groove 1402, and the third groove 1403 is used for the transition of the sliding sleeve 13 from the second groove 1402 to the first groove 1401; when the L-shaped frame 7 approaches the water outlet 29, the sliding plate 9 will drive the sliding sleeve 13 to slide along the first groove 1401, and at this time, the transmission member will control the knob 22 to rotate through the action arm 23 to control the water outlet 29 to gradually close until the sliding sleeve 13 slides into the second groove 1402, and at this time, the water outlet 29 is completely closed, and as the ice making evaporator consumes the water in the water storage box 1 through the water pumping pipe 30, the height of the floating ball 6 decreases, the sliding plate 9 will drive the sliding sleeve 13 to horizontally slide along the second groove 1402, until the floating ball 6 drops to a predetermined height, the sliding sleeve 13 will move to the intersection of the second groove 1402 and the third groove 1403, and then the transmission member will control the sliding sleeve 13 to transition from the third groove 1403 to the first groove 1401 again, and at the same time, the knob 22 is controlled to rotate to open, and refill the water storage box 1, and realize automatic water refilling after the water level of the water storage box 1 drops to a corresponding height. The buoyancy of the floating ball 6 is larger than the gravity of the counterweight sleeve 18 and the friction force generated by the operation of each sliding component.

Specifically, as shown in fig. 4 to 6, the transmission component includes a strip-shaped frame 15 slidably connected to the bottom of the U-shaped frame 21, and a gravity traction assembly for controlling the strip-shaped frame 15 to slide and return; the upper end of the sliding connection plate 9 is fixedly provided with a convex block 10, the lower end of the support arm 23 is fixedly provided with a driven rod 24, and a strip-shaped track 1501 matched with the convex block 10 and the driven rod 24 to slide is formed inside the strip-shaped frame 15; an arc-shaped groove 2101 which is matched with the driven rod 24 to penetrate is formed in the U-shaped stand 21; when the sliding sleeve 13 slides along the first groove 1401, the sliding connection plate 9 will drive the strip-shaped frame 15 to move through the projection 10, and in the process, the strip-shaped frame 15 drives the knob 22 to rotate through acting on the driven rod 24, so that the support arm 23 drives the knob 22 to rotate; when the sliding sleeve 13 moves to the intersection position of the first recess 1401 and the second recess 1402 along with the sliding plate 9, the sliding sleeve 13 will spring into the second recess 1402 under the action of the spring 12, and when the L-shaped frame 7 moves away from the water outlet 29, the sliding sleeve 13 will slide along the second recess 1402, and at this time, the sliding plate 9 will drive the protrusion 10 to horizontally slide along the strip-shaped track 1501, and the strip-shaped frame 15 should be in a standing state.

The gravity traction assembly comprises a supporting table 16 fixedly arranged at the bottom of the square frame 14 through an upright post, a vertical rod 17 is fixedly arranged at the upper end of the supporting table 16, a counterweight sleeve 18 is slidably sleeved on the outer side of the vertical rod 17, and a traction rope 20 is bolted between the side end of the strip-shaped frame 15 and the counterweight sleeve 18; a reversing wheel 19 for changing the acting direction of the traction rope 20 is arranged on the square frame 14; when the sliding sleeve 13 slides to the intersection position of the second recess 1402 and the third recess 1403, the weight sleeve 18 drags the strip frame 15 through the hauling rope 20, so that the strip frame 15 transits from the third recess 1403 to the first recess 1401 again, and at this time, the strip frame 15 drives the knob 22 to unscrew again through the pressing transmission of the driven rod 24, so as to control the continuous discharge of the water outlet head 29.

The previous description of the embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A liquid level detection and adjustment device for an ice-making evaporation system comprises a water storage box (1), and is characterized in that a water pumping pipe (30) for supplying water to an ice-making evaporator is installed on the side wall of the water storage box (1), a water delivery pipe (27) for supplying water to the inside of the water storage box is also installed on the side wall of the water storage box (1), a water outlet head (29) corresponding to the water delivery pipe (27) is installed at the inner side end of the water storage box (1), a square frame (14) is fixedly arranged at the opening end of the water storage box (1), and a knob (22) for controlling the opening and closing of the water outlet head (29) is rotatably connected to the upper end of the square frame (14);

a square frame (14) is fixedly arranged at the upper opening end of the water storage box (1), two shaft levers (2) which are symmetrically distributed are rotatably connected inside the water storage box (1), two first swing arms (3) and two second swing arms (4) are fixedly arranged at the outer ends of the two shaft levers (2), notches (301) which are matched with the second swing arms (4) to penetrate through are formed inside the first swing arms (3), and floating balls (6) are fixedly arranged at the free ends of the first swing arms (3) and the second swing arms (4);

the inner side of the water storage box (1) is connected with an L-shaped frame (7) corresponding to the first spiral arm (3) and the second spiral arm (4) in a sliding mode, the side ends of the first spiral arm (3) and the second spiral arm (4) are connected with a sliding block (8) in a rotating mode through a rotating shaft, the sliding block (8) is connected with the L-shaped frame (7) in a sliding mode, the upper side of the L-shaped frame (7) is connected with a sliding connection plate (9) in a sliding mode, and a triangular groove for guiding the sliding connection plate (9) to slide along the L-shaped frame (7) is formed in the upper end face of the square frame (14);

the upper end of square frame (14) has set firmly U type pallet (21), and goes out water head (29) and upwards run through U type pallet (21), the side of water head (29) has set firmly support arm (23), L type frame (7) are when along with first spiral arm (3) lateral shifting, through drive disk assembly control knob (22) rotation.

2. The liquid level detecting and adjusting device for the ice making evaporation system as claimed in claim 1, wherein a ball valve (26) is rotatably connected to the inside of the water pipe (27), an O-ring (28) matched with the ball valve (26) and having a closed opening is installed inside the water pipe (27), and a valve rod (25) for controlling the ball valve (26) to rotate is fixedly installed at the bottom of the knob (22).

3. The liquid level detecting and adjusting device for ice making evaporation system as claimed in claim 1, wherein a support rod (5) is fixed in the recess (301), and a strip-shaped groove (401) sliding with the support rod (5) is formed inside the second radial arm (4).

4. The liquid level detecting and adjusting device for the ice making evaporation system as claimed in claim 1, wherein a pin (11) is fixedly arranged at the bottom of the sliding plate (9), a sliding sleeve (13) is slidably sleeved outside the pin (11), and a spring (12) acting the sliding sleeve (13) downwards is sleeved outside the pin (11).

5. The liquid level detecting and adjusting device for the ice making evaporation system as claimed in claim 4, wherein the triangular groove is composed of a first groove (1401), a second groove (1402) and a third groove (1403) which are communicated, the end surface of the first groove (1401) is higher than the second groove (1402), and the third groove (1403) is used for the transition of the sliding sleeve (13) from the second groove (1402) to the first groove (1401).

6. The liquid level detection and adjustment device for ice making evaporation system as claimed in claim 1, wherein said transmission means comprises a strip frame (15) slidably connected to the bottom of the U-shaped stand (21), and a gravity traction assembly controlling the sliding return of the strip frame (15).

7. The liquid level detecting and adjusting device for ice making evaporation system as claimed in claim 6, wherein the sliding plate (9) has a protrusion (10) fixed on the upper end, the arm (23) has a driven rod (24) fixed on the lower end, and the strip frame (15) has a strip track (1501) formed inside to match the protrusion (10) and the driven rod (24) for sliding.

8. A level detecting and adjusting device for an ice-making evaporating system according to claim 7, wherein an arc-shaped slot (2101) through which the follower lever (24) is fitted is formed on the U-shaped frame (21).

9. The liquid level detecting and adjusting device for the ice making evaporation system as claimed in claim 8, wherein the gravity traction assembly comprises a supporting platform (16) fixedly arranged at the bottom of the square frame (14) through an upright column, a vertical rod (17) is fixedly arranged at the upper end of the supporting platform (16), a counterweight sleeve (18) is slidably arranged on the outer side of the vertical rod (17), and a traction rope (20) is bolted between the side end of the strip-shaped frame (15) and the counterweight sleeve (18).

10. The liquid level detecting and adjusting device for ice making evaporation system as claimed in claim 9, wherein a direction changing wheel (19) for changing the acting direction of the pulling rope (20) is installed on the square frame (14).

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