DE202022105793U1 - jet pump - Google Patents

Abstract

Jet pump, comprising a pump body (3) with a water inlet (1) and a water outlet (2), characterized in that the pump body (3) is provided with a jet pipe (4) and an impeller (5), the fluid successively the The water inlet (1), the jet pipe (4), the impeller (5) and the water outlet (2) pass through, the outer circumference of the jet pipe (4) being provided with at least one flow-increasing channel (6), the flow-increasing channel (6) being outside of the Jet pipe (4) is arranged, with the flow-increasing channel (6) being connected to the water inlet (1) and the water inlet of the impeller (5), so that the fluid flowing through the flow-increasing channel (6) flows out of the impeller (5) into the pressure-increasing cavity (12) with a valve core (7) installed in the flow increase channel (6), the valve core (7) moving in the flow increase channel (6) to open or close the flow increase channel (6). .

Description

TECHNICAL AREA

The present invention relates to the technical field of jet pumps, in particular to a jet pump.

STATE OF THE ART

A water pump is a device for pumping a liquid, comprising a motor and a pump body, the pump body being provided with a water inlet, a water inlet channel, a pressurizing chamber, a water outlet channel and a water outlet, the pressurizing chamber being provided with an impeller, the water inlet is connected to the water inlet channel, wherein the water outlet is connected to the water outlet channel, wherein the pressurizing chamber is connected to the water inlet channel and the water outlet channel, respectively. The impeller is driven by the motor to rotate at high speed, and the external water flow enters the booster chamber through the water inlet and the water inlet channel in turn. Due to the pressure increase of the impeller, a high-pressure water flow is formed and enters the water outlet channel, and then is discharged from the water outlet. When the fluid inside the impeller is discharged continuously, a low-pressure zone gradually forms in the center of the impeller and even reaches a vacuum. At this time, the fluid at the inlet of the water pump continuously flows into the impeller through the water inlet under the action of atmospheric pressure, and then is thrown out of the impeller. The impeller transfers the mechanical energy of the pump shaft to the fluid and converts it into the pressure and kinetic energy of the fluid, which is reflected in the delivery capacity of the water pump.

The performance of the water pump depends on two working parameters such as delivery head and flow rate. The curve relationship diagram of head and flow is inversely proportional. This means that the higher the head, the smaller the flow; the lower the head, the greater the flow. The water pump flow rate is limited by the water inlet channel, that is, the size of the water inlet channel directly affects the upper limit of the water pump flow rate. A degradation in performance occurs when a certain flow rate value is reached. This effect is caused by the primary cavitation generated in the area around the nozzle at the venturi opening, which not only reduces the head and efficiency of the water pump, but also causes problems such as vibration, noise and cavitation.

In order to control cavitation or mitigate the damage caused by cavitation, the main measures currently taken include impeller inlet optimization, blade load optimization, installation of induction impellers, inlet ejection supercharging, and the use of double suction structures to increase the inlet flow rate of the pump decrease and increase the inlet pressure of the pump, thereby controlling or mitigating cavitation.

The Chinese patent application with application number CN201910335203.9 and titled flow-increasing water pump discloses a pump body having a water inlet and a water outlet, the pump body being provided with a water inlet chamber, a pressure-increasing chamber and a water flow channel, the water-inlet chamber also being connected to the pressure-increasing chamber through a flow-increasing channel , wherein the flow-increasing channel is provided with a one-way check mechanism, wherein the one-way check mechanism directs the flow-increasing channel when the liquid pressure of the water inlet chamber is greater than the liquid pressure of the pressure-increasing chamber, wherein the one-way check mechanism blocks the flow-increasing channel when the liquid pressure of the water inlet chamber is lower than the liquid pressure of the pressure-increasing chamber. In the present invention, the structural design of the pump body is appropriately improved, with an additional flow-increasing passage arranged between the water inlet chamber and the pressure-increasing chamber, using the one-way check mechanism to control the conduction or blockage of the fluid flow in the flow-increasing passage according to the pressure change between the pressure-increasing chamber and the To control water inlet chamber in the pump body, whereby the curve relationship diagram of head and flow rate of the water pump is optimized and the performance of the water pump is significantly improved.

However, the subject matter of the above patent application has the following problems: the narrow flow increasing channel is provided with a one-way check mechanism, the one-way check mechanism includes a partition plate, a guide sleeve, a movable rod, a movable baffle plate, a compression spring, etc., resulting in a complicated structure, high Cost, difficult assembly and easy damage during use.

OBJECT OF THE PRESENT INVENTION

The technical problem to be solved by the present invention is to provide a jet pump which can alleviate the problem of cavitation by arranging the flow increasing passage, thereby making the production process simple and the production cost low.

The technical solution according to the present invention: jet pump, comprising a pump body with a water inlet and a water outlet, the pump body being provided with a jet pipe and an impeller, the fluid sequentially passing through the water inlet, the jet pipe, the impeller and the water outlet, wherein the outer periphery of the jet pipe is provided with at least one flow-increasing channel, the flow-increasing channel being arranged outside of the jet pipe, the flow-increasing channel being connected to the water inlet and the water inlet of the impeller, so that the fluid flowing through the flow-increasing channel is thrown out of the impeller into the pressure-increasing cavity wherein a valve core is installed in the flow increase passage, the valve core moving in the flow increase passage to open or close the flow increase passage.

Compared with the prior art, the advantage of the present invention is that the outer periphery of the jet pipe is provided with a flow-increasing duct, the flow-increasing duct is connected to the water inlet and the impeller, thereby increasing the line flow from the water outlet to the impeller.

When the jet pump has a low head, that is, when the pressure at the water inlet is greater than the predetermined value of the pressure at the impeller, the flow-increasing channel is opened, thereby further increasing the passing flow rate, effectively increasing the upper limit of the flow rate of the water pump .

When the jet pump has a high head, that is, when the pressure at the water inlet is not greater than the predetermined value of the pressure at the impeller, the flow-increasing channel is closed, thereby reducing the water inlet flow rate at the impeller, which is the upper limit of the flow rate of the water pump effectively elevated.

In the present invention, a structure of the flow-increasing duct disposed outside of the jet pipe is used. Compared to the prior art, the total volume of the entire jet pump does not increase significantly. In the present invention, the flow-increasing passage is provided with only a valve core and does not refer to other structures such as the partition plate, the guide sleeve, the movable rod, the movable baffle plate, and the compression spring. Therefore, compared to the prior art, the present invention has a simple production process and a low production cost.

When the pressure at the water inlet is greater than the predetermined value of the pressure at the impeller, the valve core moves and the flow increase channel opens.

In some exemplary embodiments of the present invention, it is provided that the outer circumference of the jet pipe is provided with a flow-increasing channel, the cross section of the flow-increasing channel being a closed or open ring structure, the flow-increasing channel being arranged around the outer circumference of the jet pipe.

It is preferably provided that the cross-section of the flow-increasing channel is a circular ring structure, with the flow-increasing channel being arranged outside the jet pipe, with the valve insert being a circular ring structure which is adapted to the cross-section of the flow-increasing channel.

It is preferably provided that the valve insert consists of an elastic material. The valve opening can be well blocked by the valve insert and the flow-increasing channel can be closed. In the present embodiment, the structure of the valve core is similar to the sealing ring and is a component with a simple structure and a mature process. Therefore, the production cost of the product is low.

In addition, since the valve core is a circular ring structure, this corresponds to the valve core being located outside the wall surface of the flow-increasing passage.

During the movement, the valve core is constrained by the wall surface of the flow increase channel, so the movement is stable and reliable.

In the present embodiment, both the flow increase channel as the valve insert also has highly symmetrical structures. Therefore, when the fluid passes through the flow increase passage or the fluid acts on the valve core, the force of the valve core is balanced, which also makes the working state of the valve core stable and reliable.

In particular, it is envisaged that the flow-increasing channel is provided with a valve opening near one side of the water inlet, the valve opening being a circular ring structure or a plurality of rectangular, circular and arcuate structures arranged regularly. When arranging the structure of the valve port, the above structure can meet the water intake demand of the flow increasing passage. A variety of rectangular, circular and arcuate structures arranged regularly can also achieve the force balance of the valve core, thereby achieving stable and reliable operation of the valve core.

In some embodiments of the present invention, the flow-increasing passage is provided with a guide piece near the wall surface at the valve opening so that the valve core located in the flow-increasing passage moves to the valve opening through the guide piece. In the present invention, by arranging the guide piece, it is ensured that the valve core can move stably and reliably to the position of the valve opening, thereby achieving blocking of the valve opening.

In some exemplary embodiments of the present invention, provision is made for the flow-increasing channel to be provided with a limiting piece, with the valve insert being arranged between the valve opening and the limiting piece. The limit piece defines the stroke of movement of the valve core to avoid the stroke of movement exceeding the limit when the valve core is heavily stressed. It is difficult to move the valve core to the valve opening position when the flow increase channel is blocked.

In some exemplary embodiments of the present invention, provision is made for the outer circumference of the jet pipe to be provided with at least two flow-increasing channels, with the cross-section of the flow-increasing channel being circular or rectangular.

In some exemplary embodiments of the present invention, it is provided that the cross section of the flow-increasing channel is a curved line segment, with at least two flow-increasing channels being arranged in a ring structure.

In some embodiments of the present invention, it is envisaged that the flow increasing channel is provided with a valve opening near a side of the water inlet. The valve core installed in the flow increase channel is adapted to the structure of the valve hole, and the valve core blocks the valve hole so that the flow increase channel is separated.

Provision is preferably made for the valve opening to be adapted to the cross section of the flow-increasing channel, the valve opening being a circular, rectangular and curved line segment. Accordingly, the valve core is a block structural member having a cross section in a circular, rectangular, and curved line segment.

It is preferably provided that the valve insert consists of an elastic material. The valve opening can be well blocked by the valve insert and the flow-increasing channel can be closed.

In the above embodiment, the flow increasing duct is generally a straight duct, which is simple in shape and low in production cost. By regularly arranging two and a larger number of flow-increasing channels, a large change in flow is achieved without substantially increasing the volume of the jet pump.

In some exemplary embodiments of the present invention, it is envisaged that the pump body is provided with a jet, the jet consisting of a jet pipe, a water inlet pipe, a pressure-increasing cavity and an impeller.

It is further provided that the water inlet pipe is connected to the water inlet, the water inlet pipe being connected to the jet pipe and the valve opening of the flow-increasing channel, the jet pipe being connected to the water inlet pipe and the pressure-increasing cavity, the flow-increasing channel being connected to the water inlet pipe and the pressure-increasing cavity , wherein the pressure increasing cavity is connected to the water outlet of the pump body. At this time, in the present invention, it is realized that the fluid enters from the water inlet and is successively discharged from the water outlet of the pump body through the water inlet pipe, the jet pipe and the booster cavity.

The conduction of the flow increase channel depends on the working condition of the jet pump. When in a conducting state, the fluid entering the water inlet pipe enters the pressure-increasing cavity through the flow-increasing passage.

In some exemplary embodiments of the present invention, it is provided that the jet comprises a first housing, a second housing, a third housing and a fourth housing.

Furthermore, it is provided that the first housing is connected to the second housing to form a water inlet pipe, the part of the jet pipe and the end of the valve opening of the flow-increasing channel being arranged in the second housing.

It is further provided that the part of the jet pipe and the part of the flow-increasing channel are arranged in the third housing, with the second housing and the third housing forming a jet pipe, with the second housing and the third housing forming a flow-increasing channel.

It is further provided that the third housing and the fourth housing form a pressure-increasing cavity.

In the present embodiment, the jet tube composed of four parts can meet the generated shape requirements and facilitate the assembly of structures such as valve core and impeller, which is a preferable structural arrangement of the present invention.

In particular, it is provided that the third housing is provided with an installation slot, the second housing being correspondingly provided with an installation section, the installation section being inserted into the installation slot, a sealing structure being arranged between the second housing and the third housing, the Sealing structure can be a sealing element in particular, wherein the second housing and the third housing can be locked by bolts.

character list

• 1 ist ein schematisches Diagramm der Struktur gemäß der vorliegenden Erfindung;
• 2 ist eine Seitenansicht gemäß der vorliegenden Erfindung;
• 3 ist eine Schnittansicht des AA-Abschnitts in 2;
• 4 ist ein schematisches Diagramm der Struktur des Strahls;
• 5 ist ein schematisches Diagramm 1 der Zerlegungsstruktur des Strahls;
• 6 ist ein schematisches Diagramm 2 der Zerlegungsstruktur des Strahls;
• 7 ist eine Schnittansicht gemäß dem Ausführungsbeispiel 6 der vorliegenden Erfindung.

The present invention will be described in more detail below in connection with drawings and preferred embodiments. However, what those skilled in the art will understand is that these drawings are drawn only for the purpose of illustrating preferred embodiments and therefore should not be used as a limitation on the scope of the present invention. Unless expressly noted, the drawings only conceptually represent the composition or construction of the object described and may contain exaggerations, and the drawings are not necessarily drawn in proportion.

• 1 Fig. 12 is a schematic diagram of the structure according to the present invention;
• 2 Fig. 12 is a side view according to the present invention;
• 3 is a sectional view of the AA section in FIG 2 ;
• 4 Figure 12 is a schematic diagram of the structure of the beam;
• 5 Fig. 1 is a schematic diagram of the decomposition structure of the beam;
• 6 Fig. 2 is a schematic diagram of the decomposition structure of the beam;
• 7 12 is a sectional view according to embodiment 6 of the present invention.

1

Wassereinlass;

2

Wasserauslass;

3

Pumpenkörper;

4

Strahlrohr;

5

Laufrad;

6

Strömungserhöhungskanal;

7

Ventileinsatz;

8

Ventilöffnung;

9

Führungsstück;

10

Begrenzungsstück;

11

Wassereinlaufrohr;

12

Druckerhöhungshohlraum;

13

Erstes Gehäuse;

14

ZweitesGehäuse;

14a

Installationsabschnitt;

15

Drittes Gehäuse;

15a

Installationsschlitz;

16

Viertes Gehäuse;

17

Ableitungskanal.

The reference numbers below are marked as follows:

1

water inlet;

2

water outlet;

3

pump body;

4

jet pipe;

5

Wheel;

6

flow increase channel;

7

valve core;

8th

valve opening;

9

guide piece;

10

boundary piece;

11

water inlet pipe;

12

booster cavity;

13

First housing;

14

secondhousing;

14a

installation section;

15

Third Housing;

15a

installation slot;

16

fourth housing;

17

drainage channel.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention is described in detail below by means of preferred embodiments in connection with the drawings.

In order to make the purpose, technical solutions and advantages of the present invention more clearly understood, the present invention will be described below in more detail in connection with drawings and working examples. It should be understood that the specific embodiments described herein are only used for understanding the present invention, but the invention is not limited thereto.

Jet pump comprising a pump body 3 with a water inlet 1 and a water outlet 2, characterized in that the pump body 3 is provided with a jet pipe 4 and an impeller 5, the fluid successively passing the water inlet 1, the jet pipe 4, the impeller 5 and the Water outlet 2 passes through, the outer periphery of the jet pipe 4 is provided with at least one flow-increasing channel 6, the flow-increasing channel 6 is arranged outside of the jet pipe 4, the flow-increasing channel 6 is connected to the water inlet 1 and the impeller 5, the flow-increasing channel connected to the water inlet and the impeller, thereby increasing the line flow from the water outlet 2 to the impeller 5, with a valve core 7 installed in the flow-increasing channel 6, the valve core 7 moving in the flow-increasing channel 6 to open or close the flow-increasing channel 6, wherein the valve insert 7 moves and the flow-increasing channel 6 opens when the pressure at the water inlet 1 is greater than the predetermined value of the pressure at the impeller 5, thereby further increasing the passing flow rate, which effectively increases the upper limit of the flow rate of the water pump, with the flow-increasing channel 6 closed when the jet pump has a high head, that is, when the pressure at the water inlet 1 is not greater than the predetermined value of the pressure at the impeller 5, thereby reducing the water inlet flow rate at the impeller 5, which effectively limits the upper limit of the flow rate of the water pump increased as in 1 shown and as in embodiment 1 in 1 until 3 shown.

In the present invention, a structure of the flow-increasing duct 6 disposed outside the jet pipe is used. Compared to the prior art, the total volume of the entire jet pump does not increase significantly. In the present invention, the flow increasing passage 6 is provided with only a valve core 7 and does not refer to other structures such as the partition plate, the guide sleeve, the movable rod, the movable baffle plate and the compression spring. Therefore, compared to the prior art, the present invention has a simple production process and a low production cost.

It is further provided that the outer circumference of the jet pipe 4 is provided with a flow-increasing channel 6, the cross section of the flow-increasing channel 6 being a closed or open ring structure, with the flow-increasing channel 6 being arranged around the outer circumference of the jet pipe 4, as in exemplary embodiment 2 in 3 until 6 shown.

It is preferably provided that the cross-section of the flow-increasing channel 6 is a circular ring structure, with the flow-increasing channel 6 being arranged outside of the jet pipe 4, with the valve insert being a circular ring structure which is adapted to the cross-section of the flow-increasing channel 6.

Provision is preferably made for the valve insert 7 to consist of an elastic material. The valve opening 8 can be well blocked by the valve insert 7 and the flow-increasing channel 6 can be closed. In the present embodiment, the structure of the valve core is similar to the sealing ring and is a component with a simple structure and a mature process. Therefore, the production cost of the product is low.

In addition, since the valve core 7 is a circular ring structure, this corresponds to the valve core 7 being located outside the wall surface of the flow-increasing passage 6 . During the movement, the valve core 7 is restricted by the wall surface of the flow-increasing passage 6, so the movement is stable and reliable.

In the present exemplary embodiment, both the flow-increasing channel 6 and the valve core 7 are highly symmetrical structures. Therefore, when the fluid passes through the flow increase passage 6 or the fluid acts on the valve core 7, the force of the valve core 7 is balanced, which also makes the working state of the valve core 7 stable and reliable.

In particular, it is provided that the flow-increasing channel 6 is provided with a valve opening 8 near one side of the water inlet 1, the valve opening 8 being a circular ring structure or a plurality of rectangular, circular and arcuate structures regularly arranged. In arranging the structure of the valve port 8, the above structure can meet the water intake demand of the flow increasing passage 6. A variety of rectangular, circular and arcuate structures arranged regularly can also achieve the force balance of the valve core 7, thereby achieving stable and reliable operation of the valve core 7.

The other contents of embodiment 2 are the same as in embodiment 1.

It is further provided that the flow-increasing channel 6 is provided with a guide piece 9 near the wall surface at the valve opening 8 so that the valve insert 7 located in the flow-increasing channel 6 moves through the guide piece 9 to the valve opening 8 . In the present invention, by arranging the guide piece 9, it is ensured that the valve core 7 can move stably and reliably to the position of the valve port 8, thereby blocking the valve port 8 is achieved, as in embodiment 3 in 3 until 6 shown.

Furthermore, it is provided that the flow-increasing channel 6 is provided with a delimiting piece 10 , with the valve insert 7 being arranged between the valve opening 8 and the delimiting piece 10 . The limit piece 10 defines the travel of the valve core 7 to prevent the travel from exceeding the limit when the valve core 7 is heavily used. It is difficult to move the valve core 7 to the position of the valve opening 8 when the flow increase channel 6 is blocked.

The other content of embodiment 3 is the same as in embodiment 2.

Furthermore, it is provided that the outer circumference of the jet pipe 4 is provided with at least two flow-increasing channels 6, the cross section of the flow-increasing channel 6 being circular or rectangular, as shown in exemplary embodiment 4.

It is further provided that the cross-section of the flow-increasing channel 6 is a curved line segment, with at least two flow-increasing channels 6 being arranged in a ring structure.

Furthermore, it is provided that the flow-increasing channel 6 is provided with a valve opening 8 close to one side of the water inlet 1 . The valve core 7 installed in the flow-increasing channel 6 is adapted to the structure of the valve hole 8, and the valve core 7 blocks the valve hole 8 so that the flow-increasing channel 6 is separated.

Provision is preferably made for the valve opening 8 to be adapted to the cross section of the flow-increasing channel 6, with the valve opening 8 being a circular, rectangular and curved line segment. Accordingly, the valve core 7 is a block structural member having a cross section in a circular, rectangular, and curved line segment.

Provision is preferably made for the valve insert 7 to consist of an elastic material. The valve opening 8 can be well blocked by the valve insert 7 and the flow-increasing channel 6 can be closed.

In the above embodiment, the flow increasing duct 6 is generally a straight duct, which is simple in shape and low in production cost. Due to the regular arrangement of two and a larger number of flow-increasing channels 6, a large change in the flow rate is achieved without essentially increasing the volume of the jet pump 3.

The other contents of embodiment 4 are the same as in embodiment 1.

Further, it is envisaged that the pump body 3 is provided with a jet, the jet comprising a jet pipe 4, a water inlet pipe 11 and a pressure-increasing cavity 12, the impeller 5 being installed in the pressure-increasing cavity 12, as in embodiment 5 in 5 and 6 shown.

It is further provided that the water inlet pipe 11 is connected to the water inlet, the water inlet pipe 11 being connected to the jet pipe 4 and the valve opening 8 of the flow increase channel 6, the jet pipe 4 being connected to the water inlet pipe 11 and the water inlet of the impeller 5, whereby the flow increasing channel 6 is connected to the water inlet pipe 11 and the water inlet of the impeller 5, so that the fluid flowing through the jet pipe 4 is thrown out of the impeller 5 into the pressurized water chamber of the pressurized cavity 12, the pressurized water chamber of the pressurized cavity 12 being connected to the water outlet 2 of the pump body 3 is connected. At this time, in the present invention, it is realized that the fluid enters from the water inlet and successively from the water outlet 2 of the pump body 3 through the Water inlet pipe 11, the jet pipe 4, the impeller 5 and the pressurized water chamber of the pressure boosting cavity 12 is derived.

The conduction of the flow increase channel 6 depends on the working condition of the jet pump. When it is in a conduction state, the fluid entering the water inlet pipe 11 enters the water inlet of the impeller 5 through the flow-increasing passage 6, so that the fluid flowing through the flow-increasing passage 6 is thrown out of the impeller 5 into the pressurized water chamber of the pressurizing cavity 12.

It is further provided that the beam comprises a first housing 13, a second housing 14, a third housing 15 and a fourth housing 16.

Furthermore, it is provided that the first housing 13 is connected to the second housing 14 to form a water inlet pipe 11 , the part of the jet pipe 4 and the end of the valve opening 8 of the flow-increasing channel 6 being arranged in the second housing 14 .

It is further provided that the part of the jet pipe 4 and the part of the flow-increasing channel 6 are arranged in the third housing 15, with the second housing 14 and the third housing 15 forming a jet pipe 4, with the second housing 14 and the third housing 15 forming one Flow increase channel 6 form.

Provision is also made for the third housing 15 and the fourth housing 16 to form a pressure-increasing cavity 12 .

In the present embodiment, the jet tube 4 composed of four parts can meet the generated shape requirements and facilitate the assembling of structures such as valve core 7 and impeller 5, which is a preferred structural arrangement of the present invention.

In particular, it is provided that the third housing 15 is provided with an installation slot 15a, the second housing 14 is correspondingly provided with an installation section 14a, the installation section 14a being inserted into the installation slot 15a, with a sealing structure between the second housing 14 and the third housing 15 is arranged, wherein the sealing structure can be a sealing member in particular, wherein the second housing 14 and the third housing 15 can be locked by bolts.

The other content of the embodiment 5 is the same as in the embodiment 3 and the embodiment 4.

Further, it is envisaged that a portion of the flow-increasing duct 6 near the impeller 5 is recorded as a discharge duct 17, the discharge duct 17 being a curved duct, the discharge outlet of the discharge duct 17 being located on the wall surface of the jet pipe 4 near the impeller 5, wherein the fluid drained through the flow-increasing duct 6 has better jet efficiency by the structural arrangement of the above drain duct 17, as in embodiment 6 in 7 shown.

In particular, it is provided that the discharge outlet of the discharge channel 17 is located in a diffusion section of the jet tube 4 . The fluid flowing through the flow-increasing channel 6 enters the jet pipe 4 and is introduced into the inlet of the pressure-increasing cavity 12 together with the fluid flowing through the jet pipe 4 . Since the discharge outlet is located in the diffusion section of the jet pipe 4, the fluid discharged through the first channel 6 and the second channel has little influence on the fluid in the jet pipe 4. The influence of the jet on increasing the turbulence of the fluid inside the flow increasing channel 6 during high-speed radiation is also avoided.

Provision is preferably made for the longitudinal section of the outer side wall surface of the discharge channel 17 to be a multi-stepped stepped surface. The fluid passes through the drain channel 17 to form some buffering on its outer wall. This avoids impingement of the fluid at the discharge outlet and influencing of the fluid inside the jet pipe 4 .

The other content of embodiment 7 is the same as one of the above embodiments.

The present application is described in detail above. The principles and embodiments of the present invention are described herein through specific examples. The description of the above embodiments is only used to facilitate the understanding of the present application and the core ideas. It should be noted that those of ordinary skill in the art can also make various improvements and modifications to the present invention without departing from the principles of the present invention. These improvements and modifications also fall within the scope of the claims of the present application.

summary

The present invention relates to a jet pump, comprising a pump body with a water inlet and a water outlet, the pump body being provided with a jet pipe and an impeller, the fluid successively passing through the water inlet, the jet pipe, the impeller and the water outlet, the outer periphery of the The jet pipe is provided with at least one flow-increasing channel, the flow-increasing channel being arranged outside the jet pipe, the flow-increasing channel being connected to the water inlet and the water inlet of the impeller, so that the fluid flowing through the flow-increasing channel is thrown out of the impeller into the pressure-increasing cavity, wherein a Valve core is installed in the flow increase channel, the valve core moving in the flow increase channel to open or close the flow increase channel. The arrangement of the flow increasing channel alleviates the problem of cavitation, making the production process simple and the production cost low.

Claims (10)

Jet pump, comprising a pump body (3) with a water inlet (1) and a water outlet (2), characterized in that the pump body (3) is provided with a jet pipe (4) and an impeller (5), the fluid successively the The water inlet (1), the jet pipe (4), the impeller (5) and the water outlet (2) pass through, the outer circumference of the jet pipe (4) being provided with at least one flow-increasing channel (6), the flow-increasing channel (6) being outside of the Jet pipe (4) is arranged, with the flow-increasing channel (6) being connected to the water inlet (1) and the water inlet of the impeller (5), so that the fluid flowing through the flow-increasing channel (6) flows out of the impeller (5) into the pressure-increasing cavity (12) with a valve core (7) installed in the flow increase channel (6), the valve core (7) moving in the flow increase channel (6) to open or close the flow increase channel (6). t. jet pump after claim 1 , characterized in that the outer circumference of the jet pipe (4) is provided with a flow-increasing channel (6), the cross-section of the flow-increasing channel (6) being a closed or open ring structure, the flow-increasing channel (6) around the outer circumference of the jet pipe (4) arranged around. jet pump after claim 2 , characterized in that the cross-section of the flow-increasing channel (6) is a circular ring structure, wherein the flow-increasing channel (6) is arranged outside the jet tube (4), wherein the valve insert (7) is a circular ring structure, which is attached to the cross-section of the flow-increasing channel ( 6) is adjusted. jet pump after claim 2 or 3 , characterized in that the flow-increasing channel (6) is provided with a valve opening (8) near one side of the water inlet (1), the valve opening (8) being a circular ring structure or a plurality of rectangular, circular and arcuate structures that are regular are arranged. jet pump after claim 1 , characterized in that the flow-increasing channel (6) is provided with a guide piece (9) near the wall surface on the valve opening (8), so that the valve insert (7) located in the flow-increasing channel (6) can be pushed through the guide piece (9). of the valve opening (8) moves. jet pump after claim 1 or 5 , characterized in that the flow-increasing channel (6) is provided with a valve opening (8) near one side of the water inlet (1), the flow-increasing channel (6) being provided with a restricting piece (10), the valve insert (7) between the Valve opening (8) and the limiting piece (10) is arranged. jet pump after claim 6 , characterized in that the outer circumference of the jet pipe (4) is provided with at least two flow-increasing channels (6), the cross-section of the flow-increasing channel (6) being circular or rectangular, the valve opening (8) being adapted to the cross-section of the flow-increasing channel (6). wherein the valve opening (8) is a circular, rectangular and curved line segment. jet pump after claim 1 , characterized in that the pump body (3) is provided with a jet, the jet consisting of a jet pipe (4), a water inlet pipe (11), a pressure-increasing cavity (12) and an impeller (5). jet pump after claim 8 , characterized in that the water inlet pipe (11) is connected to the water inlet, the water inlet pipe (11) being connected to the jet pipe (4) and the valve opening (8) of the flow-increasing channel (6), the jet pipe (4) being connected to the Water inlet pipe (11) and the water inlet of the impeller (5), the flow-increasing channel (6) being connected to the water inlet pipe (11) and the water inlet of the impeller (5), so that the fluid flowing through the jet pipe (4) and the flow-increasing channel (6) flows out of the Impeller (5) is thrown into the pressurized water chamber of the pressurizing cavity (12), the pressurized water chamber of the pressurizing cavity (12) being connected to the water outlet (2) of the pump body (3). jet pump after claim 8 , characterized in that the jet comprises a first housing (13), a second housing (14), a third housing (15) and a fourth housing (16), the first housing (13) being connected to the second housing (14) connected to form a water inlet pipe (11), the part of the jet pipe (4) and the end of the valve opening (8) of the flow increasing channel (6) being arranged in the second housing (14), the part of the jet pipe (4 ) and the part of the flow increasing channel (6) are arranged in the third housing (15), the second housing (14) and the third housing (15) forming a jet pipe (4), the second housing (14) and the third housing (15) forming a flow increasing channel (6), the third housing (15) and the fourth housing (16) forming a pressure increasing cavity (12).

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