CN212621248U - Double-meter structure for measuring pressure of refrigerant - Google Patents

Abstract

The utility model provides a two table structures for refrigerant pressure measurement belongs to mechanical technical field. This a two table structures for refrigerant pressure measurement is including the block that possesses the filler, be equipped with the cavity in the block and locate the high-pressure channel and the low pressure passageway of cavity both sides, high-pressure channel and the equal intercommunication cavity of low pressure passageway entry, high-pressure channel and low pressure passageway export all are located the block surface, the cavity internal seal is fixed with and sets up side by side and all are annular two disk seats, two disk seat bores communicate with high-pressure channel and low pressure passageway entry respectively, install the ball core between two disk seats, be equipped with the passageway that overflows that runs through in the ball core, it includes axis vertically import and row mouth to overflow the passageway, the import is through the shaping at the ball core, water conservancy diversion chamber and filler intercommunication between two disk seats and the cavity inner wall, the block is equipped with the valve rod outward, the inner of valve rod stretches into the block and is connected with the ball core, valve rod and block rotate and be connected. The utility model discloses the maloperation is few.

Description

Double-meter structure for measuring pressure of refrigerant

Technical Field

The utility model belongs to the technical field of machinery, a pressure measuring meter is related to, especially a two table structures that are used for refrigerant pressure measurement.

Background

In the debugging and maintenance of the automobile air conditioner, the refrigerant pressure of an air conditioning system needs to be measured, and a used detection instrument is generally a pointer type meter set or a digital display type meter set.

The existing meter group is as disclosed in chinese patent library a multifunctional refrigerant measurement digital display meter device [ application number: 201420394589.3, comprising a casing, a display screen on the casing, a circuit board in the casing, and an arithmetic unit, an A-D converter, a pressure sensor, a vacuum sensor, and a temperature sensor integrated on the circuit board; one end of each of the two leads is connected with the temperature sensor, and the other end of each of the two leads penetrates out of two sides of the shell and is electrically connected to the clamping arm holding the thermocouple pieces; the detection ends of the pressure sensor and the vacuum sensor are communicated with a high-pressure interface pipeline and a low-pressure interface pipeline below the shell, a high-pressure manual valve and a low-pressure manual valve are arranged on the shell corresponding to the high-pressure interface pipeline and the low-pressure interface pipeline, a glass mirror is arranged at the surface end of the shell between the high-pressure manual valve and the low-pressure manual valve, and a refrigerant access pipeline is arranged between the high-pressure interface pipeline and the low-pressure interface pipeline; and a power switch button, a mode conversion button, a light key and a vacuum degree button are arranged below the display screen on the end face of the shell.

The above digital display meter has two problems: when measuring high pressure, the high-pressure manual valve needs to be opened, and the low-pressure manual valve needs to be closed; when measuring high pressure, the opposite is true; the process is easy to cause misoperation, for example, when the high-pressure manual valve is opened, the low-pressure manual valve is still in an open state; 2. the arrangement of all parts is loose, and the volume of the whole digital display meter is large.

SUMMERY OF THE UTILITY MODEL

The utility model aims at having the above-mentioned problem to current technique, provided a two table structures that are used for refrigerant pressure measurement of compact structure and reducible maloperation.

The purpose of the utility model can be realized by the following technical proposal: a double-meter structure for measuring pressure of refrigerant comprises a block body with a filling port, a cavity and a high-pressure channel and a low-pressure channel which are arranged at two sides of the cavity are arranged in the block body, inlets of the high-pressure channel and the low-pressure channel are communicated with the cavity, outlets of the high-pressure channel and the low-pressure channel are arranged on the outer surface of the block body, the double-meter structure is characterized in that two valve seats which are arranged side by side and are annular are fixed in the cavity in a sealing manner, inner holes of the two valve seats are communicated with inlets of the high-pressure channel and the low-pressure channel respectively, a ball core is arranged between the two valve seats, a through flow passage is arranged in the ball core, the flow passage comprises an inlet and a discharge port which are vertical to the axis, the inlet is communicated with the filling port through a flow guide cavity formed between the two valve seats and the inner wall of the cavity, a, the ball core is rotated to make the row openings respectively communicated with the inner holes of the two valve seats.

Two pressure gauges for respectively detecting the pressure in the high-pressure channel and the low-pressure channel are arranged outside the block body; the using process is as follows: the refrigerant is injected from the filling port; when the refrigerant is at high pressure, the valve rod is rotated to enable the filling port to be communicated with the high-pressure channel, and the high-pressure refrigerant is discharged into the high-pressure channel through the flow guide cavity, the overflowing channel and the inner hole of the valve seat and finally discharged through the outlet of the high-pressure channel; when the refrigerant is at low pressure, the valve rod is rotated to enable the filling port to be communicated with the low-pressure channel, and the low-pressure refrigerant is discharged into the low-pressure channel through the flow guide cavity, the overflowing channel and the inner hole of the valve seat and finally discharged through the outlet of the low-pressure channel. The two pressure gauges respectively detect the pressure of the refrigerant flowing through the high-pressure channel and the low-pressure channel.

In the pressure measuring meter, the communication between the filling port and the high-pressure channel or the low-pressure channel can be realized only by arranging the ball valve assembly consisting of the valve rod, the ball core, the valve seat and the like, and the ball valve assembly is positioned between the high-pressure channel and the low-pressure channel, so that the distance between the parts can be effectively reduced, the structure of the whole pressure measuring meter is quite compact, and the volume is reduced; meanwhile, the filling port can be controlled to be communicated with the low-pressure channel or the high-pressure channel only by operating the valve rod once, and the filling port is only communicated with the low-pressure channel or the high-pressure channel after each operation, so that misoperation is effectively avoided, and the use convenience and the experience are improved.

In the above dual-meter structure for measuring pressure of refrigerant, there are two rows of ports, and the axes of the two rows of ports are vertical. The two rows of ports can reduce the rotating path of the ball core when the high-pressure channel and the low-pressure channel are switched, so that the operation is convenient.

In the double-meter structure for measuring pressure of the refrigerant, the inner hole of the valve seat is in a strip shape, the length direction of the inner hole is vertical to the axial direction of the valve rod, the inner hole is eccentrically arranged relative to the axial lead of the valve seat, and the inner holes on the two valve seats are oppositely arranged. The design disk seat hole is strip and eccentric settings, under the prerequisite that does not increase the volume, makes the manometer realize four kinds of states: 1. the filling port is communicated with the high-pressure channel, 2, the filling port is communicated with the low-pressure channel, and 3, the filling port is communicated with the high-pressure channel and the low-pressure channel; 4. the filling port is not communicated with the high-pressure channel and the low-pressure channel, so that the filling port has better practicability, and the four states are mutually independent and do not appear simultaneously, so that misoperation is further avoided.

In the above-mentioned double-surface structure for refrigerant pressure measurement, the outlet of the high-pressure channel, the outlet of the low-pressure channel and the filling port are located on the same side of the block, and the filling port is located between the outlet of the high-pressure channel and the outlet of the low-pressure channel.

In foretell a pair of table structure for refrigerant pressure measurement, two manometers set up side by side, and two manometers distribute along the disk seat axial, and the manometer includes pressure measurement mouth and display part, and two display parts set up back to back, still are equipped with two pressure measurement passageways in the block, and the entry of two pressure measurement passageways communicates high-pressure channel and low pressure passageway respectively, and the export of two pressure measurement passageways communicates two pressure measurement mouths respectively.

In the above dual-gauge structure for measuring pressure of refrigerant, the outlet of the high-pressure channel and one of the pressure gauges are arranged on a straight line, and the outlet of the low-pressure channel and the other pressure gauge are arranged on a straight line. By adopting the design, the whole pressure measuring meter has a more compact structure.

In foretell two table structures for refrigerant pressure measurement, the block in be equipped with along the bar hole of disk seat axial extension, the bar hole is located low pressure passageway one side, bar hole one end and low pressure passageway intercommunication, and the bar hole other end seals, the bar downthehole sealed be fixed with the body, body and the coaxial setting of disk seat, the body falls into the chamber one and the chamber two that arrange along the disk seat axial with the bar hole, chamber one and chamber two are through the body intercommunication, foretell chamber one is foretell cavity, still be equipped with the outage in the block, outage one end and foretell chamber two intercommunication, the body, chamber two and outage three constitute foretell high pressure channel, and the outage other end is high pressure channel's export.

In the above-mentioned double-meter structure for refrigerant pressure measurement, the one end opening that the low pressure passageway was kept away from in the bar hole and this opening is through the sealing member shutoff that links firmly with the block, and the body sticiss on one of them disk seat and form sealedly, and another disk seat sticiss on the bar hole diapire and form sealedly, be equipped with the spring that makes the body have the motion trend towards the ball core direction between body and the sealing member.

When the mounting device is mounted, the pipe body, the ball core and the valve seat are sequentially arranged in the strip-shaped hole; when the ball valve is used, a medium in the ball core is discharged into the pipe body through the corresponding valve seat and then discharged into the high-pressure channel through the pipe body; under the spring action, make body and bar hole diapire cooperation press from both sides the ball core subassembly of tight location by disk seat and ball core constitution, make above-mentioned each part accomplish the location in step to effectively reduce the equipment process, improve the equipment convenience.

In the double-meter structure for measuring pressure of the refrigerant, the drainage hole penetrates through the side wall of the pipe body, and the drainage hole is opposite to the second cavity. The drainage hole is beneficial to enabling the medium flowing into the pipe body to flow into the second cavity more quickly, and therefore pressure measuring efficiency is improved.

In foretell two table structures for refrigerant pressure measurement, the sealing member be the glass window, this glass window includes barrel and the transparent form glass piece of shaping in the barrel of spiro union in the bar is downthehole, and body and barrel coaxial arrangement. A user can visually know whether the liquid refrigerant is filled with bubbles or not through the glass sheet.

In the above-mentioned double-gauge structure for measuring pressure of refrigerant, the spring is a belleville spring, and two end faces of the belleville spring respectively abut against the cylinder and the pipe body. By adopting the design, the interference on the observation of the glass window can be effectively avoided.

As another scheme, in the above dual-surface structure for measuring pressure of a refrigerant, the sealing member is a plug fixed in the strip-shaped hole, and a side wall of the plug is in close contact with a wall of the strip-shaped hole to form a seal.

In foretell a pair of table structure for refrigerant pressure measurement, the block on have the through-hole that supplies the valve rod to stretch into, be equipped with in the through-hole and press the cover, press the cover to establish outside the valve rod, and press the cover to link firmly with the block is sealed, form sealedly through sealing washer one between valve rod and the pressure cover, and be equipped with the limit structure who is used for restricting valve rod axial motion in the through-hole.

In the above-mentioned double-surface structure for measuring pressure of refrigerant, the limit structure includes an annular convex edge formed on the inner wall of the through hole and an annular convex shoulder formed on the outer wall of the valve rod, the annular convex shoulder is located between the annular convex edge and the first sealing ring, and two end faces of the annular convex shoulder respectively abut against the inner wall of the pressing sleeve and the annular convex edge.

As another scheme, in the above dual-gauge structure for measuring pressure of refrigerant, the limiting structure includes an annular blocking edge formed on an inner wall of the pressing sleeve, a blocking ring screwed in the pressing sleeve, and an annular blocking shoulder formed on a side wall of the valve stem, and two end faces of the annular blocking shoulder respectively abut against the annular blocking edge and the blocking ring.

Compared with the prior art, this a pair of table structure for refrigerant pressure measurement has following advantage:

1. in the pressure measuring meter, the communication between the filling port and the high-pressure channel or the low-pressure channel can be realized only by arranging the ball valve assembly consisting of the valve rod, the ball core, the valve seat and the like, and the ball valve assembly is positioned between the high-pressure channel and the low-pressure channel, so that the distance between the parts can be effectively reduced, the structure of the whole pressure measuring meter is quite compact, and the volume is reduced.

2. The filling port can be controlled to be communicated with the low-pressure channel or the high-pressure channel only by operating the valve rod once, and the filling port is only communicated with the low-pressure channel or the high-pressure channel after each operation, so that misoperation is effectively avoided, and the use convenience and the experience are improved.

3. The design disk seat hole is strip and eccentric settings, under the prerequisite that does not increase the volume, makes the manometer realize four kinds of states: 1. the filling port is communicated with the high-pressure channel, 2, the filling port is communicated with the low-pressure channel, and 3, the filling port is communicated with the high-pressure channel and the low-pressure channel; 4. the filling port is not communicated with the high-pressure channel and the low-pressure channel, so that the filling port has better practicability, and the four states are mutually independent and do not appear simultaneously, so that misoperation is further avoided.

Drawings

Fig. 1 is a schematic perspective view of a dual-gauge structure for measuring pressure of a refrigerant.

Fig. 2 is a schematic cross-sectional structural view of a double-gauge structure for refrigerant pressure measurement.

Fig. 3 is a schematic view showing a connection structure of the ball core and the valve stem.

Fig. 4 is a schematic view of the structure of the valve seat.

FIG. 5 is a view showing the state of the core when the filler port communicates with the high-pressure passage.

FIG. 6 is a view showing the state of the core when the filler port communicates with the low-pressure passage.

FIG. 7 is a view showing a state of the core when the filler port communicates with both the high-pressure passage and the low-pressure passage.

FIG. 8 is a view showing the state of the core when the filler port is not in communication with both the high-pressure passage and the low-pressure passage.

In the figure, 1, block; 1a, a cavity; 1b, a high-pressure channel; 1b1, drain hole; 1b2, Chamber II; 1c, a low-pressure channel; 1d, a flow guide cavity; 1e, a pressure measuring channel; 1f, a filling port; 2. a valve seat; 2a, an inner hole; 3. a ball core; 3a, a flow passage; 3a1, inlet; 3a2, discharge; 4. a valve stem; 4a, an annular shoulder; 5. pressing the sleeve; 6. a first sealing ring; 7. a pipe body; 7a, drainage holes; 8. a second sealing ring; 9. a spring; 10. a glass window; 10a, a cylinder body; 10b, a glass sheet; 11. a pressure gauge; 12. a knob.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

Example one

As shown in fig. 1 and 2, the dual gauge structure for refrigerant pressure measurement includes a block body 1 having a filling port 1f, and a cavity 1a, and a high pressure passage 1b and a low pressure passage 1c provided at both sides of the cavity 1a are provided in the block body 1. The high pressure passage 1b and the low pressure passage 1c each have an inlet and an outlet, and in the present embodiment, the number of inlets and outlets on the high pressure passage 1b and the low pressure passage 1c is 1. Inlets of the high-pressure channel 1b and the low-pressure channel 1c are communicated with the cavity 1 a; outlets of the high pressure passage 1b and the low pressure passage 1c are located on an outer surface of the block body 1 to smoothly discharge the medium in the high pressure passage 1b or the low pressure passage 1 c.

Specifically, two valve seats 2 which are arranged in parallel and are annular are fixed in the cavity 1a in a sealing mode, the two valve seats 2 are distributed along the arrangement direction of the high-pressure channel 1b and the low-pressure channel 1c, and inner holes 2a of the two valve seats 2 are respectively communicated with inlets of the high-pressure channel 1b and the low-pressure channel 1 c. Install ball core 3 between two disk seats 2, the connected mode of ball core 3 and disk seat 2 is current: the two valve seats 2 are provided with spherical surfaces matched with the ball cores 3, and the ball cores 3 are clamped between the two spherical surfaces. As shown in fig. 2, a through flow passage 3a is arranged in the ball core 3, the flow passage 3a includes an inlet 3a1 and a discharge port 3a2, the axes of which are perpendicular, a filling port 1f is located between the two valve seats 2, the inlet 3a1 is communicated with the filling port 1f through a flow guide cavity 1d formed among the ball core 3, the two valve seats 2 and the inner wall of the cavity 1a, a valve rod 4 is arranged outside the block body 1, the outer end of the valve rod 4 is fixedly connected with a knob 12, the inner end of the valve rod 4 extends into the block body 1 and is connected with the ball core 3, the valve rod 4 is rotatably connected with the block body 1, a seal is formed between the valve rod 4 and the block body 1, and the discharge port 3a2 can be respectively.

Further, as shown in fig. 2 and 4, there are two rows of ports 3a2, and the axes of the two rows of ports 3a2 are perpendicular. The inner holes 2a of the valve seats 2 are strip-shaped, the length direction of the inner holes 2a is axially vertical to the valve rod 4, the inner holes 2a are eccentrically arranged relative to the axial lead of the valve seats 2, and the inner holes 2a on the two valve seats 2 are oppositely arranged. The inner hole 2a of the valve seat 2 is designed to be strip-shaped and eccentrically arranged, so that the pressure gauge can realize four states: 1. the filling port 1f is communicated with the high-pressure channel 1b, the filling port 2 and the filling port 1f are communicated with the low-pressure channel 1c, and the filling port 3 and the filling port 1f are communicated with the high-pressure channel 1b and the low-pressure channel 1 c; 4. the filling port 1f is not communicated with the high-pressure channel 1b and the low-pressure channel 1c, so that the filling device has better practicability, and meanwhile, the four states are mutually independent and do not appear simultaneously, so that misoperation can be effectively avoided. In this embodiment, it is preferable that the flow passage 3a is composed of three flow guiding sections which are all in a straight strip shape and are communicated with each other, and the inlet 3a1 and the two rows of outlets 3a2 are respectively located on the three flow guiding sections.

Wherein the content of the first and second substances,

the connection of the valve stem 4 and the ball element 3 is prior art, with particular reference to existing ball valves.

The valve stem 4 is mounted as follows: as shown in fig. 3, the block body 1 is provided with a through hole for the valve rod 4 to extend into, the through hole is internally provided with a pressing sleeve 5, the pressing sleeve 5 is sleeved outside the valve rod 4, the pressing sleeve 5 is fixedly connected with the block body 1 in a sealing manner, the valve rod 4 and the pressing sleeve 5 are sealed through a sealing ring 6, and the through hole is internally provided with a limiting structure for limiting the axial movement of the valve rod 4. In the embodiment, the limiting structure comprises an annular convex edge formed on the inner wall of the through hole and an annular convex shoulder 4a formed on the outer wall of the valve rod 4, the annular convex shoulder 4a is positioned between the annular convex edge and the first sealing ring 6, and two end faces of the annular convex shoulder 4a respectively abut against the inner wall of the pressing sleeve 5 and the annular convex edge.

The valve seat 2 is mounted as follows: be equipped with in the block 1 along 2 axially extended bar holes of disk seat, the bar hole is located low pressure passageway 1c one side, bar hole one end and low pressure passageway 1c intercommunication, and the bar hole other end seals. The strip-shaped hole is internally and hermetically fixed with a tube body 7, and the tube body 7 and the valve seat 2 are coaxially arranged. In this embodiment, form sealedly through two 8 sealing washers between body 7 outer wall and the bar hole pore wall. The tube body 7 divides the strip-shaped hole into a first cavity and a second cavity 1b2 which are axially arranged along the valve seat 2, the first cavity is communicated with the second cavity 1b2 through the tube body 7, the first cavity is the cavity 1a, a liquid discharge hole 1b1 is further arranged in the block body 1, one end of the liquid discharge hole 1b1 is communicated with the second cavity 1b2, the tube body 7, the second cavity 1b2 and the liquid discharge hole 1b1 form the high-pressure channel 1b, and the other end of the liquid discharge hole 1b1 is an outlet of the high-pressure channel 1 b.

Further, one end of the strip-shaped hole, which is far away from the low-pressure channel 1c, is opened and the opening is sealed by a sealing element fixedly connected with the block body 1. The tube body 7 is tightly pressed on one valve seat 2 to form a seal, the other valve seat 2 is tightly pressed on the bottom wall of the strip-shaped hole to form a seal, and a spring 9 which enables the tube body 7 to have a moving trend towards the direction of the ball core 3 is arranged between the tube body 7 and the seal. The side wall of the tube body 7 is provided with a drainage hole 7a in a penetrating way, and the drainage hole 7a is opposite to the second cavity 1b 2. The drainage hole 7a facilitates the medium flowing into the pipe body 7 to flow into the second cavity 1b2 more quickly, so that the pressure measuring efficiency is improved. Under the effect of spring 9, make body 7 and bar hole diapire cooperation press from both sides the tight 3 subassemblies of ball core that constitute of location by disk seat 2 and ball core 3, make above-mentioned each part accomplish the location in step to effectively reduce the equipment process, improve the equipment convenience.

In the present embodiment, the sealing member is a glass window 10, the glass window 10 includes a cylinder 10a screwed in the strip-shaped hole and a transparent glass sheet 10b molded in the cylinder 10a, and the tube 7 and the cylinder 10a are coaxially disposed. The user can intuitively know whether the liquid refrigerant is filled with the bubbles through the glass sheet 10 b. Preferably, the spring 9 is of the belleville type, and both end faces of the belleville spring are respectively abutted against the cylindrical body 10a and the tubular body 7.

As shown in fig. 1 and 2, two pressure gauges 11 for respectively detecting pressures in the high pressure passage 1b and the low pressure passage 1c are fixedly arranged outside the block body 1. The pressure gauge 11 is an existing product, which is commercially available. The two pressure gauges 11 are arranged in parallel, and the two pressure gauges 11 are axially distributed along the valve seat 2. The pressure gauge 11 comprises pressure measuring ports and display parts, the two display parts are arranged back to back, two pressure measuring channels 1e are further arranged in the block body 1, inlets of the two pressure measuring channels 1e are respectively communicated with the high-pressure channel 1b and the low-pressure channel 1c, and outlets of the two pressure measuring channels 1e are respectively communicated with the two pressure measuring ports. Further, the outlet of the high-pressure channel 1b, the outlet of the low-pressure channel 1c and the filling port 1f are positioned on the same side of the block body 1, and the filling port 1f is positioned between the outlet of the high-pressure channel 1b and the outlet of the low-pressure channel 1 c; the outlet of the high-pressure channel 1b and one pressure gauge 11 are distributed on a straight line, and the outlet of the low-pressure channel 1c and the other pressure gauge 11 are distributed on a straight line, so that the whole pressure gauge has a more compact structure.

The using process is as follows: the refrigerant is injected from the filling port 1 f; as shown in fig. 5, when detecting a high-pressure refrigerant, the valve rod 4 is rotated to communicate the filling port 1f with the high-pressure channel 1b, and the high-pressure refrigerant is discharged into the high-pressure channel 1b through the diversion cavity 1d, the overflow channel 3a and the inner hole 2a of the valve seat 2 and finally discharged through the outlet of the high-pressure channel 1 b; as shown in fig. 6, when detecting a low-pressure refrigerant, the valve rod 4 is rotated to communicate the filling port 1f with the low-pressure channel 1c, and the low-pressure refrigerant is discharged into the low-pressure channel 1c through the diversion cavity 1d, the overflow channel 3a and the inner hole 2a of the valve seat 2 and finally discharged through the outlet of the low-pressure channel 1 c; as shown in fig. 8, when no detection is needed, the valve rod 4 is rotated to make both rows of ports 3a2 dislocated with the inner hole 2a of the valve seat 2; when full opening is required, the valve rod 4 is rotated to connect the two rows of ports 3a2 with the internal holes 2a of the two valve seats 2, respectively, as shown in fig. 7. The two pressure gauges 11 respectively detect the pressure of the refrigerant flowing through the high-pressure channel 1b and the low-pressure channel 1 c.

Example two

The second embodiment is basically the same as the first embodiment in structure and principle, and the difference lies in: the sealing element is a plug fixed in the strip-shaped hole, and the side wall of the plug is in close contact with the wall of the strip-shaped hole to form sealing.

EXAMPLE III

The second embodiment is basically the same as the first embodiment in structure and principle, and the difference lies in: the limiting structure comprises an annular blocking edge formed on the inner wall of the pressing sleeve 5, a blocking ring screwed in the pressing sleeve 5 and an annular blocking shoulder formed on the side wall of the valve rod 4, and two end faces of the annular blocking shoulder are respectively abutted to the annular blocking edge and the blocking ring.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (10)

1. A double-meter structure for refrigerant pressure measurement comprises a block body (1) with a filling port (1f), wherein a cavity (1a) and a high-pressure channel (1b) and a low-pressure channel (1c) which are arranged on two sides of the cavity (1a) are arranged in the block body (1), inlets of the high-pressure channel (1b) and the low-pressure channel (1c) are communicated with the cavity (1a), outlets of the high-pressure channel (1b) and the low-pressure channel (1c) are located on the outer surface of the block body (1), the double-meter structure is characterized in that two valve seats (2) which are arranged in parallel and are annular are fixed in the cavity (1a) in a sealing manner, inner holes (2a) of the two valve seats (2) are respectively communicated with inlets of the high-pressure channel (1b) and the low-pressure channel (1c), a ball core (3) is arranged between the two valve seats (2), a through overflowing channel (3a) is arranged in the ball core (3), and the overflowing channel (3a) comprises an inlet (3, import (3a1) are through the water conservancy diversion chamber (1d) and the filler (1f) intercommunication of shaping between ball core (3), two valve seats (2) and cavity (1a) inner wall, block (1) is equipped with valve rod (4) outward, the inner of valve rod (4) stretches into block (1) and is connected with ball core (3), valve rod (4) and block (1) rotate to be connected and form sealedly between the two, rotate ball core (3) and can make row mouth (3a2) communicate hole (2a) of two valve seats (2) respectively.

2. The dual-gauge structure for pressure measurement of refrigerant according to claim 1, wherein there are two rows of ports (3a2), and the axes of the two rows of ports (3a2) are perpendicular.

3. The dual-meter structure for measuring pressure of refrigerant according to claim 2, wherein the inner hole (2a) of the valve seat (2) is strip-shaped, the length direction of the inner hole (2a) is axially perpendicular to the valve rod (4), the inner hole (2a) is eccentrically arranged relative to the axial line of the valve seat (2), and the inner holes (2a) of the two valve seats (2) are oppositely arranged.

4. The dual-gauge structure for refrigerant pressure measurement according to claim 1, 2 or 3, wherein the block (1) is externally provided with two pressure gauges (11) for respectively detecting pressures in the high-pressure channel (1b) and the low-pressure channel (1c), the two pressure gauges (11) are arranged in parallel, the two pressure gauges (11) are axially distributed along the valve seat (2), the pressure gauge (11) comprises a pressure measurement port and a display part, the two display parts are arranged in a back-to-back manner, the block (1) is also internally provided with two pressure measurement channels (1e), inlets of the two pressure measurement channels (1e) are respectively communicated with the high-pressure channel (1b) and the low-pressure channel (1c), and outlets of the two pressure measurement channels (1e) are respectively communicated with the two pressure measurement ports.

5. The dual-meter structure for refrigerant pressure measurement according to claim 1, wherein a strip-shaped hole extending along the axial direction of the valve seat (2) is arranged in the block body (1), the strip-shaped hole is located on one side of the low-pressure channel (1c), one end of the strip-shaped hole is communicated with the low-pressure channel (1c), the other end of the strip-shaped hole is sealed, a pipe body (7) is fixed in the strip-shaped hole in a sealing manner, the pipe body (7) and the valve seat (2) are coaxially arranged, the pipe body (7) divides the strip-shaped hole into a first cavity and a second cavity (1b2) which are axially arranged along the valve seat (2), the first cavity and the second cavity (1b2) are communicated through the pipe body (7), the first cavity is the hollow cavity (1a), a liquid discharge hole (1b1) is further arranged in the block body (1), one end of the liquid discharge hole (1b 34) is communicated with the second cavity (1b2), and the pipe body (7), the second cavity (1b2, and the other end of the liquid discharge hole (1b1) is an outlet of the high-pressure channel (1 b).

6. The double-gauge structure for pressure measurement of refrigerants according to claim 5, wherein an opening of the strip-shaped hole is far away from one end of the low-pressure channel (1c) and is blocked by a sealing element fixedly connected with the block body (1), the pipe body (7) is tightly pressed on one valve seat (2) to form a seal, the other valve seat (2) is tightly pressed on the bottom wall of the strip-shaped hole to form a seal, and a spring (9) enabling the pipe body (7) to have a movement tendency towards the direction of the ball core (3) is arranged between the pipe body (7) and the sealing element.

7. The dual-gauge structure for measuring pressure of refrigerant according to claim 6, wherein the side wall of the tube body (7) is provided with a drainage hole (7a) in a penetrating manner, and the drainage hole (7a) is opposite to the second cavity (1b 2).

8. The dual-surface structure for refrigerant pressure measurement according to claim 6 or 7, wherein the sealing member is a glass window (10), the glass window (10) comprises a cylinder (10a) screwed in the strip-shaped hole and a transparent glass sheet (10b) formed in the cylinder (10a), and the tube body (7) and the cylinder (10a) are coaxially arranged.

9. The dual-meter structure for measuring pressure of refrigerant according to claim 1, wherein the block body (1) is provided with a through hole for the valve rod (4) to extend into, a pressing sleeve (5) is arranged in the through hole, the pressing sleeve (5) is sleeved outside the valve rod (4), the pressing sleeve (5) is fixedly connected with the block body (1) in a sealing manner, a seal is formed between the valve rod (4) and the pressing sleeve (5) through a first seal ring (6), and a limiting structure for limiting axial movement of the valve rod (4) is arranged in the through hole.

10. The double-gauge structure for measuring pressure of the refrigerant according to claim 9, wherein the limiting structure comprises an annular convex edge formed on the inner wall of the through hole and an annular convex shoulder (4a) formed on the outer wall of the valve rod (4), the annular convex shoulder (4a) is positioned between the annular convex edge and the first sealing ring (6), and two end faces of the annular convex shoulder (4a) are respectively abutted against the inner wall of the pressing sleeve (5) and the annular convex edge.

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