CN117654080A - Negative pressure high-efficiency material flash evaporation system - Google Patents

Abstract

The invention discloses a negative pressure efficient material flash evaporation system, which relates to the technical field of material flash evaporation and comprises a tank body, wherein a discharge hole is formed in the bottom end of the tank body, a feed pipe is arranged on the outer wall of the tank body, an exhaust pipe is arranged at the top end of the tank body, a steam check valve is arranged on the outer wall of the exhaust pipe, and the inner cavity of the tank body is separated by a separation mechanism; the separation mechanism comprises a mounting seat; the device also comprises a connecting mechanism and a shielding mechanism. According to the flash evaporation tank, the separation mechanism, the connecting mechanism and the shielding mechanism are arranged, when materials are accumulated to a preset degree, the motor is started to drive the separation plate to displace to separate the tank body, at the moment, the movable plate is separated from the separation plate, the movable plate continues to move to drive the discharge port to be opened, so that the materials below the separation plate can be discharged, the discharge port is closed after the materials are discharged, and the separation plate is opened, so that flash evaporation operation can be performed during discharging, and the effect of discharging the flash evaporation tank without stopping the machine is achieved.

Description

Negative pressure high-efficiency material flash evaporation system

Technical Field

The invention relates to the technical field of material flash evaporation, in particular to a negative pressure efficient material flash evaporation system.

Background

Flash evaporation refers to the phenomenon that saturated liquid at high pressure becomes saturated vapor at the pressure of a container due to sudden decrease in pressure after the saturated liquid enters the container at relatively low pressure. The flash tank functions to provide means for rapid vaporization of the fluid and vapor-liquid separation. The principle of flash evaporation is as follows: the higher the pressure, the higher the boiling point of the water and the higher the heat content; when the pressure is reduced, part of sensible heat is released, and the part of excessive heat is absorbed in the form of latent heat, so that part of water is flash evaporated into steam, and the rapid dehydration of the material is realized.

In the process of removing the moisture in the material, the material enters a flash tank through a feed pipe, and liquid contained in the material is evaporated into gas and then discharged through an exhaust pipe; after the exhaust operation is completed, the materials need to be discharged from the discharge hole and collected. However, when the material is discharged, the discharge port is opened, which causes a change in the air pressure in the tank body, and continuous production operation cannot be performed. Therefore, the materials are discharged after the machine is stopped in the actual production process. The production efficiency can be influenced by stopping the flash tank for discharging, so that the purpose of discharging the flash tank without stopping the flash tank is achieved, and a negative-pressure efficient material flash system is provided.

Disclosure of Invention

The invention aims at: in order to achieve the purpose of discharging the flash tank without stopping the machine, the negative pressure high-efficiency material flash system is provided.

In order to achieve the above purpose, the present invention provides the following technical solutions: the negative pressure high-efficiency material flash evaporation system comprises a tank body, wherein the upper part of the inner cavity of the tank body is connected with negative pressure suction equipment through an exhaust pipe; the bottom end of the tank body is provided with a discharge hole, the outer wall of the tank body is provided with a feed pipe, the top end of the tank body is provided with an exhaust pipe, the outer wall of the exhaust pipe is provided with a steam check valve, and the inner cavity of the tank body is separated by a separation mechanism;

the separating mechanism comprises a mounting seat, the mounting seat is fixedly connected to the outer wall of the tank body and is positioned below the feeding pipe, the inner wall of the mounting seat is connected with a separating plate in a sliding mode, the separating plate extends to the inner wall of the tank body, the inside of the mounting seat is positioned at the top end of the separating plate, a clamping groove is formed in the bottom end of the separating plate, a movable plate is arranged at the bottom end of the mounting seat, a movable groove for the movable plate to slide is formed in the inside of the mounting seat, a motor is mounted on the outer wall of the mounting seat, a first screw rod is connected to the output end of the motor, the first screw rod penetrates through the movable plate, a clamping block and a sliding block are connected to the inside of the separating plate in a sliding mode, a first spring is connected between the clamping block and the sliding block, connecting rods are connected to the outer wall of the sliding block in a rotating mode, and one ends of the connecting rods are connected with guide rods in a rotating mode, and the guide rods are connected to the inside of the separating plate in a sliding mode. The separation plate and the movable plate are fixedly connected through a connecting mechanism; the discharging hole is opened and closed through a shielding mechanism.

As still further aspects of the invention: the connecting mechanism comprises a fixed block, the fixed block is connected with the inside of the movable plate in a sliding mode and extends into the inside of the partition plate, a second spring is connected between the fixed block and the movable plate, a fixed groove for the fixed block to be inserted is formed in the bottom end of the partition plate, a second screw rod extending into the inner wall of the fixed block is connected with the inside of the movable plate in a rotating mode, a first bevel gear is fixedly connected to the bottom end of the second screw rod, the inside of the movable plate is located in the first bevel gear, a second bevel gear is connected with the outer wall of the first bevel gear in a rotating mode, a third screw rod is fixedly connected with one end of the second bevel gear, a pushing block is connected to the outer wall of the third screw rod, a transverse groove is formed in the outer wall of the movable plate in a sliding mode and extends into an inner cavity of the transverse groove, and a cross rod is fixedly connected to one side of the inner wall of the movable groove.

As still further aspects of the invention: the shielding mechanism comprises a groove and a baffle, the baffle is rotationally connected to the inner cavity of the discharge hole, one end of the baffle is fixedly connected with a connecting shaft, one end of the connecting shaft is fixedly connected with a spur gear, the groove is formed in the bottom end of the movable plate, a lug is fixedly connected to the bottom end of the inner wall of the movable groove, a displacement frame which extends out of the lug is connected to the mounting seat in a sliding manner, a third spring is connected between the displacement frame and the mounting seat, and the displacement frame is in contact with the spur gear.

As still further aspects of the invention: the outer wall of the movable plate is provided with a threaded hole, the threaded hole is matched with the first screw rod, and the outer wall of the movable plate is attached to the inner wall of the movable groove.

As still further aspects of the invention: the inner wall of draw-in groove with the outer wall of fixture block laminates mutually, the top of fixture block is provided with first inclined plane, the bottom of slider is provided with the second inclined plane, the inside of division board has been seted up and has been supplied the guide bar carries out gliding displacement groove.

As still further aspects of the invention: the outer wall of fixed block with the inner wall of fixed slot is laminated mutually, the ejector pad is located the one end of horizontal groove inner chamber is provided with the third inclined plane, the inner wall of horizontal groove with the outer wall of horizontal pole is laminated mutually.

As still further aspects of the invention: the inner wall of the fixed block is provided with balls matched with the second screw rod, the inner wall of the pushing block is provided with balls matched with the third screw rod, and the first bevel gear is meshed with the second bevel gear.

As still further aspects of the invention: the inner wall of the groove is attached to the outer wall of the lug, and a fourth inclined plane is arranged at one end of the displacement frame extending out of the lug.

As still further aspects of the invention: the outer wall of the displacement frame is provided with tooth grooves, and the tooth grooves are meshed with the spur gears.

Compared with the prior art, the invention has the beneficial effects that:

through being provided with separating mechanism, coupling mechanism and shelter from the mechanism, when the material piles up the degree of predetermineeing, starter motor drives the division board displacement and separates the jar body, fly leaf and division board separation this moment, and the fly leaf continues to remove and drives the discharge gate and open for the material of dividing the baffle below can be discharged, closes the discharge gate after the discharge, opens the division board again, thereby when making the ejection of compact, also can carry out the flash distillation operation, thereby reaches the effect of carrying out the ejection of compact to the flash tank non-stop.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the mounting base of the present invention;

FIG. 3 is a schematic view showing the internal structure of the movable plate according to the present invention;

FIG. 4 is an enlarged view of FIG. 3A in accordance with the present invention;

FIG. 5 is a schematic view of the mounting structure of the fixed block and the push block of the present invention;

FIG. 6 is a schematic view of the mounting structure of the displacement frame of the present invention;

fig. 7 is a schematic structural view of a displacement frame according to the present invention.

In the figure: 1. a tank body; 2. a discharge port; 3. a feed pipe; 4. an exhaust pipe; 5. a steam check valve; 6. a partition mechanism; 601. a mounting base; 602. a partition plate; 603. a clamping groove; 604. a movable plate; 605. a movable groove; 606. a motor; 607. a first screw rod; 608. a clamping block; 609. a slide block; 610. a first spring; 611. a connecting rod; 612. a guide rod; 7. a connecting mechanism; 701. a fixed block; 702. a second spring; 703. a fixing groove; 704. a second screw rod; 705. a first bevel gear; 706. a second bevel gear; 707. a third screw rod; 708. a pushing block; 709. a transverse groove; 710. a cross bar; 8. a shielding mechanism; 801. a groove; 802. a bump; 803. a displacement frame; 804. a third spring; 805. a baffle; 806. a connecting shaft; 807. spur gears.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-7, in an embodiment of the present invention, a negative pressure high-efficiency material flash evaporation system includes a tank 1, wherein an upper portion of an inner cavity of the tank 1 is connected with a negative pressure suction device through an exhaust pipe; the bottom end of the tank body 1 is provided with a discharge port 2, the outer wall of the tank body 1 is provided with a feed pipe 3, the top end of the tank body 1 is provided with an exhaust pipe 4, the outer wall of the exhaust pipe 4 is provided with a steam check valve 5, and the inner cavity of the tank body 1 is separated by a separation mechanism 6; the separation mechanism 6 comprises a mounting seat 601, the mounting seat 601 is fixedly connected to the outer wall of the tank body 1 and is positioned below the feeding pipe 3, a separation plate 602 is slidably connected to the inner wall of the mounting seat 601, the separation plate 602 extends to the inner wall of the tank body 1, a clamping groove 603 is formed in the inner portion of the mounting seat 601 and positioned at the top end of the separation plate 602, a movable plate 604 is arranged at the bottom end of the separation plate 602, a movable groove 605 for the movable plate 604 to slide is formed in the inner portion of the mounting seat 601, a motor 606 is mounted on the outer wall of the mounting seat 601, a first screw rod 607 is connected to the output end of the motor 606, the first screw rod 607 penetrates through the movable plate 604, a clamping block 608 and a sliding block 609 are slidably connected to the inner portion of the separation plate 602, a first spring 610 is connected between the clamping block 608 and the sliding block 609, connecting rods 611 are rotatably connected to the outer walls of the clamping block 608 and the sliding block 609, one ends of the connecting rods 611 are rotatably connected with guide rods 612, and the guide rods 612 are slidably connected to the inner portion of the separation plate 602; the separation plate 602 and the movable plate 604 are fixedly connected through a connecting mechanism 7; the discharge hole 2 is opened and closed by a shielding mechanism 8.

In this embodiment: the negative pressure suction device can perform suction operation on the interior of the tank body 1 through the suction pipe, so that the interior of the tank body 1 is in a low pressure or negative pressure state. When the material is required to be discharged, the inner cavity of the tank body 1 is firstly separated, the motor 606 is started, the motor 606 operates to drive the first screw rod 607 to rotate, the first screw rod 607 rotates to drive the movable plate 604 to slide in the movable groove 605, at the moment, the movable plate 604 is fixedly connected with the partition plate 602 through the matching of parts in the connecting mechanism 7, the movable plate 604 is displaced to drive the partition plate 602 to move, the partition plate 602 moves into the inner cavity of the tank body 1, and the inner cavity of the tank body 1 is separated. To ensure the sealing effect, a sealing rubber strip can be arranged at the contact part of the partition plate 602 and the inner cavity of the tank body 1.

When the partition plate 602 separates the can body 1, at this time, the movable plate 604 is separated from the partition plate 602 by the matching of the parts in the connecting mechanism 7, the movable plate 604 continues to move and is separated from the sliding block 609, the guide rod 612 can only move transversely, the clamping block 608 and the sliding block 609 are enabled to move synchronously under the action of the first spring 610, the guide rod 612 and the connecting rod 611, at this time, the sliding block 609 slides out of the partition plate 602, and the clamping block 608 moves into the clamping groove 603, so that the partition plate 602 is automatically fixed.

When the movable plate 604 resets, the movable plate 604 contacts with the sliding block 609 to push the sliding block 609 to move, so as to drive the clamping block 608 to displace out of the clamping groove 603, and the fixation of the partition plate 602 is canceled.

Referring to fig. 2-5, the connection mechanism 7 includes a fixed block 701, the fixed block 701 is slidably connected to the inside of the movable plate 604 and extends into the inside of the partition plate 602, a second spring 702 is connected between the fixed block 701 and the movable plate 604, a fixed slot 703 into which the fixed block 701 is inserted is provided at the bottom end of the partition plate 602, a second screw 704 extending into the inner wall of the fixed block 701 is rotatably connected to the inside of the movable plate 604, a first bevel gear 705 is fixedly connected to the bottom end of the second screw 704, a second bevel gear 706 is rotatably connected to the outer wall of the movable plate 604, a third screw 707 is fixedly connected to one end of the second bevel gear 706, a push block 708 is connected to the outer wall of the third screw 707, a transverse slot 709 is provided on the outer wall of the movable plate 604, the push block 708 is slidably connected to the inside of the movable plate 604 and extends into the inner cavity of the transverse slot 709, and a cross rod 710 is fixedly connected to one side of the inner wall of the movable slot 605.

In this embodiment: when the partition plate 602 separates the inner cavity of the can body 1, at this time, the cross rod 710 moves into the cross slot 709, the cross rod 710 pushes the push block 708 to move, the push block 708 moves to drive the third screw rod 707 to rotate, the third screw rod 707 rotates to drive the second bevel gear 706 to rotate, the second bevel gear 706 rotates to drive the first bevel gear 705 to rotate, the first bevel gear 705 rotates to drive the second screw rod 704 to rotate, the second screw rod 704 rotates to drive the fixed block 701 to move out of the fixed slot 703, and the second spring 702 is extruded, so that the partition plate 602 is separated from the movable plate 604.

When the partition plate 602 is reset, the push block 708 is separated from the cross bar 710, the fixed block 701 is displaced into the fixed groove 703 by the elastic force of the second spring 702, and the partition plate 602 is fixedly connected with the movable plate 604.

Referring to fig. 5-7, the shielding mechanism 8 includes a groove 801 and a baffle 805, the baffle 805 is rotatably connected to the inner cavity of the discharge port 2, one end of the baffle 805 is fixedly connected with a connecting shaft 806, one end of the connecting shaft 806 is fixedly connected with a spur gear 807, the groove 801 is opened at the bottom end of the movable plate 604, the bottom end of the inner wall of the movable groove 605 is fixedly connected with a bump 802, the inside of the mounting seat 601 and the bump 802 is slidably connected with a displacement frame 803 extending out of the bump 802, a third spring 804 is connected between the displacement frame 803 and the mounting seat 601, and the displacement frame 803 is in contact with the spur gear 807.

In this embodiment: the baffle 805 is used for shielding the discharge hole 2, when the separation plate 602 separates the tank 1, the movable plate 604 is separated from the separation plate 602, the movable plate 604 continues to move, the protruding block 802 enters the groove 801 until the movable plate 604 contacts with the displacement frame 803, the displacement frame 803 is pushed to move, the displacement frame 803 displaces to drive the spur gear 807 to rotate, the spur gear 807 rotates to drive the connecting shaft 806 to rotate, and the connecting shaft 806 rotates to drive the baffle 805 to rotate, so that the discharge hole 2 is opened.

When the material is piled up to a preset degree (a transparent observation window can be arranged on the outer wall of the tank body 1, the highest limit condition of the material is monitored), the starting motor 606 drives the separation plate 602 to move to separate the tank body 1, then the movable plate 604 is separated from the separation plate 602, and the movable plate 604 continues to move to drive the discharge port 2 to be opened, so that the material below the separation plate 602 can be discharged. After the material is discharged, the discharge port 2 is closed, and the partition plate 602 is opened, so that the flash evaporation operation can be performed during discharging, and the effect of discharging the flash tank without stopping the machine is achieved. In order to ensure that the pressure in the tank body 1 always meets the requirement, a pressure sensor can be arranged on the inner wall of the upper end of the tank body 1 and used for detecting the pressure change state; once the internal pressure does not meet the preset low pressure value, the negative pressure suction device is started to perform suction operation when the previous batch of materials is emptied and the next batch of materials does not enter the tank body 1, so as to adjust the pressure value in the tank body.

Referring to fig. 2, the outer wall of the movable plate 604 is provided with a threaded hole, the threaded hole is matched with the first screw rod 607, and the outer wall of the movable plate 604 is attached to the inner wall of the movable groove 605.

In this embodiment: the motor 606 operates to drive the first screw rod 607 to rotate, the first screw rod 607 rotates to drive the movable plate 604 to slide in the movable groove 605, the movable plate 604 is displaced to drive the separation plate 602 to move, and the separation plate 602 moves into the inner cavity of the tank 1 to separate the inner cavity of the tank 1.

Referring to fig. 2-4, the inner wall of the clamping groove 603 is attached to the outer wall of the clamping block 608, a first inclined surface is disposed at the top end of the clamping block 608, a second inclined surface is disposed at the bottom end of the sliding block 609, and a displacement groove for sliding the guide rod 612 is disposed inside the partition plate 602.

In this embodiment: when the partition plate 602 separates the can body 1, at this time, the movable plate 604 is separated from the partition plate 602 by the matching of the parts in the connecting mechanism 7, the movable plate 604 continues to move and is separated from the slide block 609, the guide rod 612 can only move transversely, the clamp block 608 and the slide block 609 are under the action of the guide rod 612 and the connecting rod 611, so that the clamp block 608 and the slide block 609 move synchronously, at this time, the slide block 609 slides out of the partition plate 602, and the clamp block 608 moves into the clamping groove 603, so that the partition plate 602 is automatically fixed.

Referring to fig. 2 and 5, the outer wall of the fixed block 701 is attached to the inner wall of the fixed slot 703, a third inclined surface is disposed at one end of the push block 708 located in the inner cavity of the transverse slot 709, the inner wall of the transverse slot 709 is attached to the outer wall of the cross bar 710, balls matched with the second screw rod 704 are disposed on the inner wall of the fixed block 701, balls matched with the third screw rod 707 are disposed on the inner wall of the push block 708, and the first bevel gear 705 is meshed with the second bevel gear 706.

In this embodiment: the cross rod 710 is displaced to enter the cross slot 709, the cross rod 710 pushes the push block 708 to move, the push block 708 is displaced to drive the third screw rod 707 to rotate, the third screw rod 707 is rotated to drive the second bevel gear 706 to rotate, the second bevel gear 706 is rotated to drive the first bevel gear 705 to rotate, the first bevel gear 705 is rotated to drive the second screw rod 704 to rotate, the second screw rod 704 is rotated to drive the fixed block 701 to be displaced out of the fixed slot 703, and the second spring 702 is extruded, so that the partition 602 is separated from the movable plate 604.

Referring to fig. 5-7, an inner wall of the groove 801 is attached to an outer wall of the bump 802, a fourth inclined plane is disposed at an end of the displacement frame 803 extending out of the bump 802, a tooth slot is disposed on an outer wall of the displacement frame 803, and the tooth slot is engaged with the spur gear 807.

In this embodiment: the baffle 805 is used for shielding the discharge hole 2, when the separation plate 602 separates the tank 1, the movable plate 604 is separated from the separation plate 602, the movable plate 604 continues to move, the protruding block 802 enters the groove 801 until the movable plate 604 contacts with the displacement frame 803, the displacement frame 803 is pushed to move, the displacement frame 803 displaces to drive the spur gear 807 to rotate, the spur gear 807 rotates to drive the connecting shaft 806 to rotate, and the connecting shaft 806 rotates to drive the baffle 805 to rotate, so that the discharge hole 2 is opened.

The foregoing description is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical solution of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (9)

1. The negative pressure high-efficiency material flash evaporation system comprises a tank body (1), wherein the upper part of an inner cavity of the tank body (1) is connected with negative pressure suction equipment through an exhaust pipe; the novel steam boiler is characterized in that an inner cavity of the tank body (1) is separated by a separation mechanism (6);

the separation mechanism (6) comprises a mounting seat (601), the mounting seat (601) is fixedly connected to the outer wall of the tank body (1) and is positioned below the feeding pipe (3), the inner wall of the mounting seat (601) is slidably connected with a separation plate (602), the separation plate (602) extends to the inner wall of the tank body (1), the inside of the mounting seat (601) is positioned at the top end of the separation plate (602) and is provided with a clamping groove (603), the bottom end of the separation plate (602) is provided with a movable plate (604), the inside of the mounting seat (601) is provided with a movable groove (605) for the movable plate (604) to slide, the outer wall of the mounting seat (601) is provided with a motor (606), the output end of the motor (606) is connected with a first screw (607), the first screw (607) penetrates through the movable plate (604), the inside of the separation plate (602) is slidably connected with a clamping block (608) and a sliding block (609), the clamping block (608) is connected with the sliding block (609), the inside of the tank body is provided with a guide rod (611) and one end of the guide rod (612) is connected with the rotary rod (609), the guide rod (612) is slidably connected to the inside of the partition plate (602); the separation plate (602) and the movable plate (604) are fixedly connected through a connecting mechanism (7); the discharging hole (2) is opened and closed through a shielding mechanism (8).

2. The negative pressure efficient material flash evaporation system according to claim 1, wherein the connecting mechanism (7) comprises a fixed block (701), the fixed block (701) is slidably connected to the inside of the movable plate (604) and extends into the inside of the partition plate (602), a second spring (702) is connected between the fixed block (701) and the movable plate (604), a fixed groove (703) into which the fixed block (701) is inserted is formed in the bottom end of the partition plate (602), a second screw rod (704) extending into the inner wall of the fixed block (701) is rotatably connected to the inside of the movable plate (604), a first bevel gear (705) is fixedly connected to the bottom end of the second screw rod (704), a second bevel gear (706) is rotatably connected to the outer wall of the movable plate (604), a third screw rod (708) is fixedly connected to one end of the second bevel gear (706), a pushing block (604) is formed in the outer wall of the partition plate (602), and a cross rod (605) is connected to the inner wall of the movable plate (604) by a sliding groove (709).

3. The negative pressure efficient material flash evaporation system according to claim 2, wherein the shielding mechanism (8) comprises a groove (801) and a baffle (805), the baffle (805) is rotationally connected to an inner cavity of the discharge port (2), one end of the baffle (805) is fixedly connected with a connecting shaft (806), one end of the connecting shaft (806) is fixedly connected with a spur gear (807), the groove (801) is formed in the bottom end of the movable plate (604), a bump (802) is fixedly connected to the bottom end of the inner wall of the movable groove (605), a displacement frame (803) extending out of the bump (802) is slidingly connected to the inside of the mounting seat (601), a third spring (804) is connected between the displacement frame (803) and the mounting seat (601), and the displacement frame (803) is in contact with the spur gear (807).

4. The negative pressure efficient material flash evaporation system according to claim 1, wherein a threaded hole is formed in the outer wall of the movable plate (604), the threaded hole is matched with the first screw rod (607), and the outer wall of the movable plate (604) is attached to the inner wall of the movable groove (605).

5. The negative pressure efficient material flash evaporation system according to claim 1, wherein an inner wall of the clamping groove (603) is attached to an outer wall of the clamping block (608), a first inclined plane is arranged at the top end of the clamping block (608), a second inclined plane is arranged at the bottom end of the sliding block (609), and a displacement groove for sliding the guide rod (612) is formed in the partition plate (602).

6. The negative pressure efficient material flash evaporation system according to claim 2, wherein the outer wall of the fixed block (701) is attached to the inner wall of the fixed groove (703), a third inclined plane is arranged at one end of the push block (708) located in the inner cavity of the transverse groove (709), and the inner wall of the transverse groove (709) is attached to the outer wall of the transverse rod (710).

7. The negative pressure efficient material flash evaporation system according to claim 2, wherein the inner wall of the fixed block (701) is provided with balls matched with the second screw (704), the inner wall of the pushing block (708) is provided with balls matched with the third screw (707), and the first bevel gear (705) is meshed with the second bevel gear (706).

8. The negative pressure efficient material flash evaporation system according to claim 3, wherein an inner wall of the groove (801) is attached to an outer wall of the protruding block (802), and a fourth inclined plane is arranged at one end of the displacement frame (803) extending out of the protruding block (802).

9. A negative pressure high efficiency material flash evaporation system according to claim 3, wherein the outer wall of the displacement frame (803) is provided with tooth grooves, which are engaged with the spur gear (807).