CN219273079U - Detection room and detection vehicle - Google Patents

Abstract

The utility model provides a detection chamber and a detection vehicle, wherein the detection chamber comprises a storage mechanism, a spur gear mechanism and an adjusting assembly, wherein the storage mechanism comprises a storage bin and partition plates arranged in the storage bin in the longitudinal direction, the spur gear mechanism comprises a support rod which transversely extends through each partition plate, spur teeth arranged on the support rod, and the adjusting assembly is arranged on each partition plate and is engaged with the spur teeth, and the adjusting assembly is configured to rotate under the action of external force so as to enable the partition plates to move on the support rod in the axial direction. The utility model can simultaneously carry or reasonably combine the detection instruments in different projects, thereby enabling the detection chamber to have the capability of detecting variety.

Description

Detection room and detection vehicle

Technical Field

The utility model relates to the field of petrochemical engineering, in particular to a detection chamber and a detection vehicle.

Background

Professional detection work and quality management work are needed to be carried out on various aspects such as atmosphere, environment, building materials and the like at each stage of petrochemical engineering construction.

Currently, there are various mobile detection laboratories on the market, such as a mobile laboratory for detecting the atmosphere, a mobile laboratory for detecting the environment, or a mobile laboratory for detecting a building material, which have certain limitations, and the environmental monitoring vehicle cannot meet the requirements of material inspection on the building material, the pipeline installation material, and the like in petrochemical engineering construction, and is used in a mobile monitoring laboratory for civil engineering material, and also cannot meet the requirements of inspection and detection on the pipeline material in petrochemical engineering construction.

Mobile laboratories have become a necessity in petrochemical engineering construction, however, existing mobile detection laboratories still have the following problems:

(1) The mobile laboratory in the prior art can only detect a single detection item, so that the efficiency of engineering construction and the accuracy of information acquisition can be seriously reduced.

(2) The insufficient management of the information causes a hysteresis in the acquisition of the information, thus delaying the period of engineering construction.

Disclosure of Invention

The utility model aims to provide a detection chamber which can simultaneously carry or reasonably combine detection instruments in different projects, so that the detection chamber has the capability of detecting variety, therefore, the detection chamber can simultaneously carry out multiple detection in petrochemical engineering construction, and multiple detection results can be mutually combined and verified, thereby obviously improving the accuracy of information acquisition. In addition, the utility model can upload information such as sampling, detection process images, site reports and the like in real time, thereby improving the management capability of the information and further improving the speed and efficiency of engineering construction. In addition, the utility model also provides a detection vehicle.

According to a first aspect of the present utility model there is provided a detection chamber comprising a storage mechanism for a first detection instrument, comprising at least one storage compartment configured in a frame-like form, and a plurality of spaced apart partitions longitudinally disposed within the storage compartment,

a spur gear mechanism comprising a supporting rod extending transversely through each partition plate, a plurality of equally-spaced spur teeth axially arranged on the supporting rod, and

an adjustment assembly disposed on each of the baffles and in engagement with the spur gear,

wherein the adjustment assembly is configured to rotate under the influence of external force to cause axial movement of the diaphragm on the support rod.

In one embodiment, the adjusting assembly comprises a gear meshed with the spur gear, a bearing rod and a hand wheel, wherein a first end of the bearing rod is fixedly connected with the hand wheel, and a second end of the bearing rod vertically extends through the gear to form a fixed connection.

In one embodiment, the number of teeth of the gear is in the range of 17 to 27.

In one embodiment, a sliding rail is provided on the inner wall of the storage compartment that is connected to the partition, allowing the partition to slide laterally within the storage compartment.

In one embodiment, the storage mechanism further comprises a plurality of fixed joints disposed on the support rod for limiting the axial movement path of the partition plate on the support rod.

In one embodiment, the first detection instrument comprises at least one of a foundation load capacity detector, a rebar tensile tester, a semi-or full-quantitative spectroscopic detector, and an endoscope.

In one embodiment, the detection chamber comprises an experiment mechanism arranged in parallel with the storage mechanism, wherein the experiment mechanism comprises a first operation table which is arranged along the transverse direction and used for data acquisition and analysis, a clean water tank which is fixedly connected with the first operation table and used for cleaning and preparing solution, and a sewage treatment tank which is connected with the bottom end of the clean water tank.

In one embodiment, the detection chamber further comprises a second console configured in a rectangular configuration for placement of a second detection instrument, and an instrument securing tool, wherein the instrument securing tool comprises a tabletop rail disposed on the second console, and a tensioner disposed between the second console and the storage mechanism.

According to a second aspect of the present utility model there is provided a test vehicle comprising a test chamber according to the above.

In one embodiment, the detection vehicle comprises a wire rope damper fixedly connected with the storage bin in the storage mechanism.

Compared with the prior art, the utility model has the advantages that: according to the utility model, the axial position of each baffle plate on the support rod can be changed, so that the sizes of different chambers in the storage bin can be adjusted, and further, detection instruments for different detection items (such as atmospheric detection, environmental detection or building material detection) can be more easily mounted. In addition, the utility model can carry or reasonably combine the detection instruments in different projects at the same time, so that the detection chamber has the capability of detecting variety, therefore, the detection chamber can simultaneously carry out multiple detection in petrochemical engineering construction, and multiple detection results can be mutually combined and verified, thereby obviously improving the accuracy of information acquisition. In addition, the utility model can upload information such as sampling, detection process images, site reports and the like in real time, thereby improving the management capability of information of the detection vehicle and further improving the speed and efficiency of engineering construction.

Drawings

The utility model will be described in detail below with reference to the attached drawing figures, wherein:

fig. 1 schematically shows the structure of a test vehicle according to the present utility model;

FIG. 2 is a schematic structural view of a storage mechanism in a detection chamber according to the present utility model;

FIG. 3 is a partial schematic view of a storage mechanism in a detection chamber showing the engagement of an adjustment assembly with a spur gear mechanism in accordance with the present utility model.

In the drawings, like parts are designated with like reference numerals. The figures are not drawn to scale.

Detailed Description

In order to make the technical solution and advantages of the present utility model more apparent, exemplary embodiments of the present utility model will be described in further detail below with reference to the accompanying drawings. It will be apparent that the described embodiments are only some of the embodiments of the present utility model and are not exhaustive of all embodiments. And embodiments of the utility model and features of the embodiments may be combined with each other without conflict.

Fig. 1 schematically shows the structure of a test vehicle 200 according to the present utility model.

As shown in fig. 1, a test vehicle 200 according to the present utility model mainly includes a test chamber 100 and a storage mechanism 1 provided in the test chamber 100. The internal chamber of the storage mechanism 1 can be deformed freely so as to adequately accommodate each of the first detecting instruments (not shown). The contents of which are described below.

According to one embodiment of the utility model, the first detection instrument includes, but is not limited to, a foundation load bearing capacity detector, a rebar tensile tester, a semi-or full-quantitative spectroscopic tester, and an endoscope. It is easy to understand that the first detecting instrument in the present utility model is mainly a conventional detecting instrument designed for the detection of the atmosphere, the environment, the building materials, etc. in each stage of the petrochemical engineering construction.

Fig. 2 is a schematic structural view of the storage mechanism 1 in the detection chamber 100 according to the present utility model. According to the utility model, as shown in fig. 2, the storage means 1 comprise at least one storage compartment 11 which is configured in the form of a frame and a partition 13. Wherein the storage compartment 11 is configured to limit the maximum distance of the first detection instrument in the longitudinal direction. The partition plates 13 are provided in a plurality and are each disposed in the storage bin 11 in the longitudinal direction, and the plurality of partition plates 13 are each arranged at intervals in the lateral direction. Thereby, a plurality of chambers are formed between the storage bin 11 and the plurality of partitions 13, so that a plurality of first detecting instruments can be more easily accommodated at the same time.

In one embodiment, connectors (not shown) are provided on the outer wall of the storage bin 11 to enable a plurality of storage bins 11 to be arranged in a stacked longitudinal direction to form further chambers for receiving the first detection instrument.

According to the utility model, as shown in fig. 2, the detection chamber 100 further comprises a spur gear mechanism 12 and an adjustment assembly 2. Wherein the spur gear mechanism 12 extends transversely through each of said partition plates 13 and the adjustment assembly 2 is brought into engagement with the spur gear mechanism 12. Specifically, the adjustment assembly 2 is configured to rotate under the influence of external force, thereby causing the diaphragm 13 to move laterally on the spur gear mechanism 12, thereby enabling the position of the diaphragm 13 to be more easily adjusted, and further enabling the chamber within the storage bin 11 to more easily house different volumes of first detection instruments.

Since the volumes and types of the detecting instruments for different detecting items are greatly different, the detecting laboratory in the prior art can only carry the detecting instrument for a single detecting item. Compared with the prior art, the utility model can adjust the size of each chamber in the storage bin 11 by changing the transverse position of different partition plates 13 on the spur gear mechanism 12, so that the detection instrument for different detection items (such as for atmospheric detection, for environmental detection or for building material detection) can be more easily mounted. Therefore, if the utility model is applied to each stage of petrochemical engineering construction, the mounting requirements of detection instruments of different detection projects can be met only by changing the transverse position of the partition plate 13 on the spur gear mechanism 12, so that the engineering construction efficiency is obviously improved.

According to one embodiment of the present utility model, the storage mechanism 1 may also carry or reasonably combine the detection apparatuses in different projects at the same time, so that the detection chamber 100 has the capability of detecting diversity of types. Therefore, the detection room 100 can simultaneously carry out multiple detection in petrochemical engineering construction, and multiple detection results can be combined and verified mutually, so that the accuracy of information acquisition is remarkably improved.

Fig. 3 is a partial schematic view of the storage mechanism 1 in the detection chamber 100 according to the present utility model, showing the engagement relationship of the adjustment assembly 2 with the spur gear mechanism 12. In one embodiment, as shown in fig. 3, the spur gear mechanism 12 includes a support rod 121 disposed within the storage bin 11, and spur teeth 122 disposed on the support rod 121. Wherein the support rods 121 extend transversely through each partition 13, and the straight teeth 122 are provided in a plurality and are all equally distributed on the support rods 121 in the axial direction. It will be readily appreciated that the tooth space of the spur tooth 122 in the present utility model is always consistent with the tooth space of the gear 21 (described below), thereby ensuring that the adjustment assembly 2 is always in a stable operating condition at the support rod 121.

In one embodiment, as shown in fig. 3, the adjustment assembly 2 includes a gear 21. Wherein the gear 21 is disposed in the partition 13 above the support bar 121 so as to be engaged with the support bar 121 through the straight teeth 122 on the support bar 121. Therefore, the gear 21 can move transversely on the support rod 141 more stably under the action of the straight teeth 122 to adjust the position of each partition 13, so as to meet the mounting requirement of the detecting instrument in different detecting projects.

In one embodiment, as shown in fig. 3, the adjustment assembly 2 further includes a bearing bar 22 and a hand wheel 23. The first end of the bearing rod 22 is fixedly connected to the centre of the hand wheel 23, thereby enabling the bearing rod 22 to rotate with the hand wheel 23 at the same frequency. In one embodiment of the utility model, the handwheel 23 is configured in a disk-like configuration, thereby facilitating rotation to drive axial movement of the diaphragm 13 over the support rod 121.

In one embodiment, as shown in FIG. 3, the second end of the bearing rod 22 extends through the gear 21 to form a fixed connection. Specifically, a hollow sleeve 131 is provided on the partition 13, and the bearing rod 22 is configured to be capable of extending through the hollow sleeve 131 to be fixedly connected to the gear 21 and to the inner peripheral surface of the gear 21. It will be readily appreciated that the gear 21 can rotate with the hand wheel 23 following the bearing bar 22 as the hand wheel 23 is rotated.

In one embodiment, the number of teeth of gear 21 is in the range of 17 to 27. For example, the number of teeth of the gear 21 is 27, and the gear 21 can make the distance of the baffle 13 moving on the support rod 121 along the transverse direction smaller, so that the chamber matched with the volume of the first detecting instrument can be adjusted more accurately. For example, the number of teeth of the gear 21 is 17, and the gear 21 at this time can make the distance of the partition 13 moving on the support rod 141 in the lateral direction larger, so that the size of the chamber in the storage mechanism 1 can be adjusted more quickly to improve the efficiency of engineering construction.

In one embodiment, the storage mechanism 1 further comprises a stationary joint (not shown). The fixing sections are provided in plurality and are all provided on the support rod 121, so that the position of the partition 13 on the support rod 121 can be effectively restricted. Therefore, the gear 21 can make the partition 13 more stable under the restriction of the fixed joint.

In another embodiment, fixing joints can be placed on two sides of each partition 13, so that stability of the partition 13 in the working process is guaranteed, and safety of the detecting instrument is guaranteed.

According to the utility model, as shown in fig. 1, the detection chamber 100 further comprises an experimental setup 3. The experiment mechanism 3 and the storage mechanism 1 are arranged in parallel. Specifically, the storage mechanism 1 and the experiment mechanism 3 are located on both sides in the detection chamber 100. Therefore, the inspection chamber 100 can more easily perform inspection work for different items.

In one embodiment, as shown in FIG. 1, the facility 3 includes a first operation panel 31, a clean water tank 32, and a sewage treatment tank 33. Wherein the first console 31 is disposed in the detection chamber 100 in the lateral direction. The data collection and analysis of the data in the different items can be performed on the first console 31. The clean water tank 32 is disposed in the detection chamber 100 in the lateral direction and is connected to the first operation table 31. The operation of preparing the solution and the operation of cleaning a second measuring instrument (not shown) can be performed on the clean water tank 32. A sewage treatment tank 33 is connected to the bottom end of the clean water tank 32 to receive wastewater for periodic treatment.

In one embodiment, the inspection vehicle 200 further includes an information management unit (not shown). Which communicates with the first console 31 in the inspection room 100, so that information such as sampling, inspection process images, and site reports can be uploaded in real time, thereby improving the management capability of information of the inspection vehicle 200, and further improving the speed and efficiency of engineering construction. In one embodiment of the utility model, the information management unit includes, but is not limited to, a sample management module, an order delivery module, a report issue module, a data upload module, a management inspector module, and the like. It will be readily appreciated that the various modules may be suitably adapted for different test items.

According to the utility model, as shown in fig. 1, the detection chamber 100 further comprises a second console 4 and an instrument holder. Wherein the second console 4 is configured in a rectangular configuration and can be used for placement of a second detection instrument. The instrument-securing means comprises a table-top rail (not shown) provided on the second console 4, and a tensioner 401 provided between the second console 4 and the storage mechanism 1. Wherein, the desktop guide rail is the inner groove form and is lower than the test bench surface. The desktop guide rail is mainly used for fixing equipment with a support on the equipment body, and specifically, the supporting legs of the equipment body can be embedded into the grooves so as to prevent the equipment from sliding in the plane direction of the test bed. Tensioner 401 is an elastic strap with a bayonet that can act to bind the instrument to secure the instrument to the table rail. Therefore, the stability of the second detecting instrument can be effectively maintained under the action of the tensioner 401 and the table top guide rail, so that the accuracy of the detecting result can be improved.

According to one embodiment of the utility model, the second detection instrument includes, but is not limited to, a test tube, a measuring cup, and a pipette. It is easy to understand that the second detecting instrument in the present utility model is mainly a conventional detecting instrument designed for the detection of the atmosphere, the environment, the building material, etc. in each stage of the petrochemical engineering construction.

In one embodiment, the inspection vehicle includes a wire rope damper (not shown) fixedly connected to the storage bin 11 of the storage mechanism 1, so that the inspection instrument in the storage bin 11 can be ensured to have good stability. In addition, a hard surface-changing foaming shock pad (not shown) is paved on the inner wall of the storage bin 11 and the partition plate 13, so that on one hand, the detection instrument placed in the storage bin 11 can be sufficiently clamped, and the stability of the detection instrument in the detection chamber 100 is improved; on the other hand, the outer wall surface of the detection instrument can be effectively protected, so that the instrument is effectively prevented from being damaged in the transportation process.

In one embodiment of the present utility model, the present utility model is further equipped with necessary systems such as an electrical system (including UPS power, a gasoline generator 5 with rated output power of 7KW, and a 220V mobile charging high-power source (not shown), the capacity of which can be up to 20000mAh or more, to meet the requirements of the detecting instruments for different items in the detecting room 100), a lighting system, a vibration-proof system, a network system (using a wireless 4G, 5G network), and the like. This is well known to those skilled in the art and will not be described in detail.

The present utility model provides a detection chamber and a detection vehicle, which can adjust the size of different chambers in a storage bin 11 by changing the axial position of each partition 13 on a support rod 121, and can further easily carry detection instruments of different detection items (for example, for atmospheric detection, for environmental detection or for building materials detection). In addition, the utility model can carry or reasonably combine the detection instruments in different projects at the same time, so that the detection chamber 100 has the capability of detecting variety, therefore, the detection chamber 100 can simultaneously carry out multiple detection in petrochemical engineering construction, and multiple detection results can be combined and verified mutually, thereby obviously improving the accuracy of information acquisition. In addition, the utility model can upload information such as sampling, detection process images, site reports and the like in real time, thereby improving the information management capability of the detection vehicle 200 and further improving the speed and efficiency of engineering construction.

The above is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto. Modifications and variations may readily be made by those skilled in the art within the scope of the present disclosure, and such modifications and variations are intended to be included within the scope of the present utility model. Therefore, the protection scope of the utility model is subject to the protection scope of the claims.

Claims (10)

1. A detection chamber, comprising:

a storage mechanism (1) for placing a first detection instrument, comprising at least one storage compartment (11) configured in a frame-like form, and a number of spaced-apart partitions (13) arranged longitudinally within the storage compartment (11),

a spur gear mechanism (12) comprising a support rod (121) extending transversely through each of the partition plates (13), and a plurality of equally spaced spur teeth (122) axially disposed on the support rod (121), an

An adjustment assembly (2) provided on each of said partitions (13) and forming an engagement with said spur toothing (122),

wherein the adjustment assembly (2) is configured to rotate under the influence of an external force to cause the diaphragm (13) to move axially on the support rod (121).

2. The detection chamber according to claim 1, characterized in that the adjustment assembly (2) comprises a gear wheel (21) in engagement with the spur tooth (122), a bearing rod (22), and a hand wheel (23), wherein a first end of the bearing rod (22) is fixedly connected to the hand wheel (23) and a second end extends vertically through the gear wheel (21) forming a fixed connection.

3. A detection chamber according to claim 2, characterized in that the number of teeth of the gear wheel (21) is in the range of 17 to 27.

4. A detection chamber according to claim 3, characterized in that on the inner wall of the storage compartment (11) there are provided sliding rails (111) connected to the partition (13) allowing the partition (13) to slide laterally inside the storage compartment (11).

5. The detection chamber according to claim 4, characterized in that the storage means (1) further comprise a number of fixed joints arranged on the support rod (121) and adapted to limit the axial movement path of the partition (13) on the support rod (121).

6. The inspection chamber of claim 5, wherein the first inspection instrument comprises at least one of a foundation load capacity inspection instrument, a rebar tensile tester, a semi-or full-quantitative spectroscopy instrument, and an endoscope.

7. The detection chamber according to claim 6, characterized in that it comprises an experimental mechanism (3) arranged parallel to the storage mechanism (1), said experimental mechanism (3) comprising a first operating table (31) arranged in a transversal direction and intended for data acquisition and analysis, a clean water tank (32) fixedly connected to said first operating table (31) and intended for washing and preparing a solution, and a sewage treatment tank (33) connected to the bottom end of said clean water tank (32).

8. The detection chamber according to claim 7, further comprising a second console (4) configured in a rectangular configuration for placing a second detection instrument, and an instrument securing tool, wherein the instrument securing tool comprises a tabletop rail arranged on the second console (4), and a tensioner (401) arranged between the second console (4) and the storage mechanism (1).

9. A test vehicle comprising a test chamber according to any one of claims 1 to 8.

10. The inspection vehicle according to claim 9, characterized in that it comprises a wire rope damper fixedly connected to the storage compartment (11) in the storage mechanism (1).

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